The URL can be used to link to this page

Home My WebLink About1640 SANDALWOOD LN; ; PC2020-0051; PermitBuilding Permit Finaled Print Date: 07/19/2023 Job Address: 1640 SANDALWOOD LN, Permit Type: BLDG-Plan Check Parcel#: 2051305900 Valuation: $0.00 Occupancy Group: #of Dwelling Units: Bedrooms: Bathrooms: Occupant Load: Code Edition: Sprinkled: Project Title: Plan Check Permit CARLSBAD, CA 92008-2618 Work Class: Track#: Lot#: Project#: Plan#: Construction Type: Orig. Plan Check#: Plan Check#: Residential Permit No: Status: {_ City of Carlsbad PC2020-0051 Closed -Finaled Applied: 12/14/2020 Issued: 03/30/2021 Finaled Close Out: 03/29/2022 Final Inspection: INSPECTOR: Description: GEESEY: 798 SF SECOND FLOOR LIVING ADDITION// 700 SF REMODEL KITCHEN TO KITCHEN// 567 SF ATTACHED 2ND FLOO ADU// 139 SF STAIRS AND DECK TO ADU Applicant: DAVID GEESEY 1640 SANDALWOOD LN CARLSBAD, CA 92008-2618 (760) 707-3910 FEE MANUAL BLDG PLAN CHECK FEE Total Fees: $500.00 Building Division Property Owner: CO-OWNERS GEESEY DAVID AND BETH 1640 SANDALWOOD LN CARLSBAD, CA 92008-2618 Total Payments To Date: $500.00 Balance Due: 1635 Faraday Avenue, Carlsbad CA 92008-7314 I 442-339-2719 I 760-602-8560 f I www.carlsbadca.gov AMOUNT $500.00 $0.00 Page 1 of 1 r/ RESIDENTIAL ~ City of BUILDING PERMIT Plan Check )-)('2..020-005{ Est. Value ~~c;G,,ro'l Carlsbad APPL1cAT10N B-1 PC Deposit 00.oO Date 12-14'-2c1ZD P,,DV i"-1~42-~,,,,.J.Jr.1ocJ L,,. Job Address 1640 Sandalwood Lane, Carlsbad CA 92008 Suite: ___ _,...,PN: 205-130-59-00 CT/Project #: __________________ ,Lot #: ____ Year Built: _1...;9_6;...7 _______ _ Fire Sprinklers: ()vEs@ NO Air Conditioning:Q YES Q NO Electrical Panel Upgrade: QYEs0 NO BRIEF DESCRIPTION OF WORK: Remodel kitchen. Add ADU above Kitchen. Add Bed and Bath on second floor. Add A/C. ~ Addition/New: _____ Living SF, 798 Deck SF, ____ Patio SF, ____ Garage SF __ _ Is this to create an Accessory Dwelling Unit? 0Y ON New Fireplace? OY 0 N, if yes how many? __ □Remodel:_ SF of affected area Is the area a conversion or change of use ? OY 0 N 0 Pool/Spa: _____ .SF Additional Gas or Electrical Features? ___________ _ OSolar: ___ .KW, ___ Modules, Mounted:0Roof 0Ground, Tilt: 0 YON, RMA: Ov ON, Battery:OY 0N, Panel Upgrade: Ov 0N ~ Reroof: Entire roof ·--------------------------------- ~ Plumbing/Mechanical/Electrical Add Bathroom and ADU 0 Only: Other: This permit is to be issued in the name of the Property Owner as Owner-Builder, licensed contractor or Authorized Agent of the owner or contractor. The person listed as the Applicant below will be the main point af contact throughout the permit process. PROPERTY OWNER Name: David Geesey Address: 1640 Sandalwood Lane APPLICANT Iii PROPERTY OWNERS AUTHORIZED AGENT Name: None APPLICANT 0 Address: __________________ _ City: Carlsbad State: CA Zip: 92008 City: __________ State: __ _.Zip:. ____ _ Phone: 760-707-3910 Phone: __________________ _ Email: Safari123089@amail.com Email: ___________________ _ DESIGN PROFESSIONAL Name: None APPLICANT O CONTRACTOR OF RECORD APPLICANT 0 Name:, __________________ _ Address: _______________ _ Address: _________________ _ City: _______ .State: __ _.Zip: ___ _ City: __________ State: ___ .Zip:, ______ _ Phone: ________________ _ Phone: __________________ _ Email: Safari123089@gmail.com Email: __________________ _ Architect State License: __________ _ State License/class: ______ Bus. License: ____ _ 1635 Faraday Ave Carlsbad, CA 92008 Ph: 760-602-2719 Fax: 760-602-8558 Email: ~lJ.i!_g_j_Qg_@_~c1r_ls_tladca.ga_y_ REV. 08/20 IDENTIFY WHO WILL PERFORM THE WORK BY COMPLETING (OPTION A) OR (OPTION B) BELOW: {OPTION A): LICENSED CONTRACTOR DECLARATION: I hereby affirm under penalty of perjury that I am licensed under provisions of Chapter 9 (commencing with Section 7000} of Division 3 of the Business and Professions Code, and my license is in fufl force and effect. I also affirm under penalty of perjury one of the following declarations: 01 have and will maintain a certificate of consent to self-insure for workers' compensation provided by Section 3700 of the Labor Code, for the performance of the work which this permit is issued. Policy No. _________________________________________ _ DI have and wit I maintain worker's compensation, as required by Section 3700 of the labor Code, for the performance of the work for which this permit is issued. My workers' compensation insurance carrier and policy number are: lnsuranceCompany Name: ______________________ _ Policy No. ____________________________ Expiration Date: _______________ _ D Certificate of Exemption: t certify that in the performance of the work for which this permit is issued, I shall not employ any person in any manner so as to become subject to the workers' compensation Laws of California. WARNING: Failure to secure workers compensation coverage is unlawful and shall subject an employer to criminal penalties and civil fines up to $100,000.00, in addition the to the cost of compensation, damages as provided for in Section 3706 of the Labor Code, interest and attorney's fees. CONSTRUCTION LENDING AGENCY, IF ANY: I hereby affirm that there is a construction lending agency for the performance of the work this permit is issued {Sec. 3097 (i) Civil Code). Lender's Name: ______________________ Lender's Address: _____________________ _ CONTRACTOR PRINT: _________ SIGN: _________ DATE: {OPTION B): OWNER-BUILDER DECLARATION: I hereby affirm that I am exempt from Contractor's license Law for the following reason: ~ I, as owner of the property or my employees with wages as their sole compensation, wilt do the work and the structure is not intended or offered for sale (Sec. 7044, Business and Professions Code: The Contractor's License Law does not apply to an owner of property who builds or improves thereon, and who does such work himself or through his own employees, provided that such improvements are not intended or offered for sale. If, however, the building or improvement is sold within one year of completion, the owner-builder will have the burden of proving that he did not build or improve for the purpose of sale). DI, as owner of the property, am exclusively contracting with licensed contractors to construct the project (Sec. 7044, Business and Professions Code: The Contractor's License Law does not apply to an owner of property who builds or improves thereon, and contracts for such projects with contractor(s) licensed pursuant to the Contractor's License Law). DI am exempt under Business and Professions Code Division 3, Chapter 9, Article 3 for this reason: 0 1owner Builder acknowledgement and verification form" has been filled out, signed and attached to this application. D Owners ''Authorized Agent Form" has been filled out, signed and attached to this application giving the agent authority to obtain the permit on the owner's behalf. By my signature below I acknowledge that, except for my personal residence in which I must have resided for at least one year prior to completion of the improvements covered by this permit, I cannot legally sell a structure that I have built as an owner-builder if it has not been constructed in its entirety by licensed contractors. I understand that a copy of the applicable law, Section 7044 of the Business and Professions Code, is available upon request when this application is submitted or at the following Web site: http://www./eginfo.ca.gov/calaw 5 .h 1 t 6 m1N.: /~ ~ OWNER PRINT: David Geesey {,..._ .v ... .,4~"'-------·-7 _____ DATE: 12/11/2020 APPLICANT CERTIFICATION: SIGNATURE REQUIRED AT THE TIME OF SUBMITTAL By my signature below, f certify that: I am the property owner or State of California Licensed Contractor or authorized to act on the property owner or contractor's behalf f certify that I have read the application and state that the above information is correct and that the information on the plans is accurate. I agree to comply with all City ordinances and State laws relating to building construction. f hereby authorize representative of the City of Carlsbad to enter upon the above mentioned property for inspection purposes. I ALSO AGREE TO SAVE, INDEMNIFY AND KEEP HARMLESS THE CITY OF CARLSBAD AGAINST ALL LIABILITIES, JUDGMENTS, COSTS AND EXPENSES WHICH MAY IN ANY WAY ACCRUE AGAINST SAID CITY IN CONSEQUENCE OF THE GRANTING OF THIS PERMIT. OSHA: An OSHA permit is required for excavations over 5'0' deep and demolition or construction of structures over 3 stories in height. APPLICANT PRINT: David Geesey SIGN: ---=Qd _ _,____~ ____ DATE: 12/11/2020 1635 Faraday Ave Carlsbad, CA 92008 Ph: 760-602-2 719 Fax: 760-602-8558 Email: Buil_dj.!JE.@_G.1.d?b.idt.;;~.£.QV 2 REV 0B/20 { City of Carlsbad OWNER-BUILDER ACKNOWLEDGEMENT FORM B-61 Development Services Building Division 1635 Faraday Avenue 760-602-2719 www.carlsbadca.gov OWNER-BUILDER ACKNOWLEDGMENT FORM Pursuant to State af California Health and Safety Code Section 19825-19829 To: Property Owner An application for construction permit(s) has been submitted in your name listing you as the owner··builder of the property located at: Site Address 1640 Sandalwood Lane, Carlsbad CA 92008 The City of Carlsbad ("City") is providing you with this Owner-Builder Acknowledgment and Verification form to inform you of the responsibilities and the possible risks associated with typical construction activities issued in your name as the Owner-Builder. The City will not issue a construction permit until you have read and initialed your understanding of each provision in the Property Owner Acknowledgment section below and sign the form. An agent of the owner cannot execute this notice unless you, the property owner, complete the Owner's Authorized Agent form and it is accepted by the City of Carlsbad. INSTRUCTIONS: Please read and initial each statement below to acknowledge your understanding and verification of this information by signature at the bottom of the form. These are very important construction related acknowledgments designed to inform the property owner of his/her obligations related to the requested permit activities. I. DG I understand a frequent practice of unlicensed contractors is to have the property owner obtain an "Owner Builder" building permit that erroneously implies that the property owner is providing his or her own labor and material personally. I, as an Owner-"Builder, may be held liable and subject to serious financial risk for any injuries sustained by an unlicensed contractor and his or her employees while working on my property. My homeowner's insurance may not provide coverage for those injuries. I am willfully acting as an Owner-Builder and am aware of the limits of my insurance coverage for injuries to workers on my property. II. DG I understand building permits are not required to be signed by property owners unless they are responsible for the construction and are not hiring a licensed contractor to assume this responsibility. Ill. DG I understand as an "Owner Builder" I am the responsible party of record on the permit. I understand that I may protect myself from potential financial risk by hiring a licensed contractor and having the permit filed in his or her name instead of my own. IV. DG I understand contractors are required by law to be licensed and bonded in California and to list their license numbers on permits and contracts. V. DG I understand if 1 employ or otherwise engage any persons, other than California licensed contractors, and the total value of my construction is at least five hundred dollars ($500), including labor and materials, I may be considered an "employer" under state and federal law. 1 REV. 08/20 Owner-Builder Acknowledgement Continued VI. DG I understand if I am considered an "employer" under state and federal law, I must register with the state and federal government, withhold payroll taxes, provide workers' compensation disability insurance, and contribute to unemployment compensation for each "employee." I also understand my failure to abide by these laws may subject me to serious financial risk. VII. DG I understand under California Contractors' State License Law, an Owner Builder who builds single family residential structures cannot legally build them with the intent to offer them for sale, unless all work is performed by licensed subcontractors and the number of structures does not exceed four within any calendar year, or all of the work is performed under contract with a licensed general building contractor. VIII. DG I understand as an Owner.Suilder if I sell the property for which this permit is issued, I may be held liable for any financial or personal injuries sustained by any subsequent owner(s) which result from any latent construction defects in the workmanship or materials. IX. DG I understand I may obtain more information regarding my obligations as an "employer" from the Internal Revenue Service, the United States Small Business Administration, the California Department of Benefit Payments, and the California Division of Industrial Accidents. I also understand I may contact the California Contractors' State License Board (CSLB) at 1--800-321--CSLB (2752) or www.cslb.ca.gov for more information about licensed contractors. X. DG I am aware of and consent to an Owner-Builder building permit applied for in my name, and understand that I am the party legally and financially responsible for proposed construction activity at the following address: 1640 Sandalwood Lane, Carlsbad CA 92008 XI. DG I agree that, as the party legally and financially responsible forthis proposed construction activity, I will abide by all applicable laws and requirements that govern Owner-··Builders as well as employers. XII. DG I agree to notify the issuer of this form immediately of any additions, deletions, or changes to any of the information I have provided on this form. Licensed contractors are regulated by laws designed to protect the public. If you contract with someone who does not have a license, the Contractor's State License Board may be unable to assist you with any financial loss you may sustain as a result of a complaint. Your only remedy against unlicensed Contractors may be in civil court. It is also important for you to understand that if an unlicensed Contractor or employee of that individual or firm is injured while working on your property, you may be held liable for damages. If you obtain a permit as Owner-- Builder and wish to hire contractors, you will be responsible for verifying whether or not those contractors are properly licensed and the status of their workers' compensation coverage. Before a building permit can be issued, this form must be completed, signed by the property owner and returned to the City of Carlsbad Building Division. I declare under penalty of perjury that I have read and understand all of the information provided on this form and that my responses, including my authority to sign this form, is true and correct. I am aware that I have the option to consult with legal counsel prior ta signing this form, and I have either (1) consulted with /ego/ counsel prior to signing this form or (2) have waived this right in signing this form without the advice of legal counsel. David Geesey Property Owner Name (PRINT) 2 12/11/2020 Date REV. 08/20 solidforms 9474 Kearny Villa Rd, Suite 215, San Diego, CA 92126 Evan Coles, P.E. (858) 376-7734 evan@solidformseng.com STRUCTURAL CALCULATIONS Geesey Residence 1640 Sandalwood Ln, Carlsbad, CA 92008 12-07-2020 : Project # 20-076 Table of Contents RE(~r=IVED CITY OF CA0~LSBAD BUILDING DIVISION Design Criteria & Loads .................................................. 1 Gravity Analysis & Design .............................................. 2-11 Lateral Analysis & Design .............................................. 12-24 Foundation Analysis & Design ..................................... 25 Design Criteria Building Code: Concrete: Masonry: Mortar: Grout: Reinforcing Steel: Structural Steel: Bolting: Welding: Wood: Soil: Design Loads Load 1 DL Asphalt Shingle Roof Plywood Joists Insulation Drywall Electrical/Mech./Misc. Other Total DL LL Residential Roof Total Load Load 3 DL carpet & Pad Floor Plywood Joists Insulation Drywall Elec./Mech./Misc. Other Total DL LL Residential Floor Total Load solidforms engineering 2018 IBC/2019 CBC -ASCE / SE! 7-16 AC! 318-14 [f,; 2500 psi -No Special Inspection Req.'d (U.N.O.)] TMS 402-16/ACI 530-16 [Normal Wt.-ASTM C90-fm;l500 psi-Spec. Insp. Req.'d] ASTM C270 [r, ; 1800 psi Type SJ ASTM C476 [r, ; 2000 psi] ASTM A615 [Fy ; 40 ksi For #4 Bars & Smaller/ Fy ; 60 ksi For #5 Bars & Larger] AISC 360-16, 15th Edition W Shapes (I Beams): HSS Shapes (Rect.): ASTM A992, High Strength, Low Alloy, Fy ; 50 ksi ASTM AS00, carbon Steel, Fy ; 46 ksi HSS Shapes (Round): ASTM AS00, carbon Steel, Fy ; 42 ksi Pipe Shapes: All other steel: ASTM A53, Grade B, carbon Steel, Fy ; 35 ksi ASTM A36, Fy ; 36 ksi A307 / A325-N / A490-N (Single Plate Shear Conn.) E70 Series Typ. (E90 Series for A615 Grade 60 Reinforcing Bars) Shop welding to be done in an approved fabricator's shop. Field welding to have continuous Special Inspection. NDS-15 Soil Classification (Table 1806.2): Allowable Bearing Pressure ; Lateral Bearing Pressure ; Active Pressure ; At-rest Pressure ; Coefficient of Friction ; psf Load 2 4.0 DL Torch Down Roof 1.5 Plywood 3.5 Joists 1.5 Insulation 2.5 Drywall 1.0 Elec./Mech./Misc. 0.0 Other 14 Total DL 20 LL Residential Roof 34 Total Load QSf Load4 4.0 DL Tile & Mortar 1.5 Plywood 3.5 Joists 1.5 Insulation 2.5 Drywall 1.0 Elec./Mech./Misc. a.a Other 14 Total DL 40 LL Residential Deck 54 Total Load (SW, SP, SM, SC, GM, & GC) 1500 psf (Table 1806.2) 150 psf/ft (Table 1806.2) 30 psf/ft (Table 1610.1) 60 psf/ft (Table 1610.1) 0.25 (Table 1806.2) psf Int. Wall 6.0 DL Drywall 1.5 2x4 Studs @ 16"o.c. 3.5 Misc. 1.5 Other 2.5 Total Load 1.0 a.a Ext. Wall 1 16 DL Stucco 20 2x4 Studs @ 16"o.c. 36 Drywall Insulation Misc. psf Other 24.0 Total Load 1.5 3.5 Ext. Wall 2 1.5 2.5 1.0 0.0 34 60 94 Page 1 of 25 12/07/20 Qsf 5.0 1.0 1.0 7 QSf 10.0 1.0 2.5 1.5 1.0 16 solidforms engineering Page 2 of 25 12/07/20 I Multiple Simple Beam ■!(◄·83',11ltltif.f@• !134e81§►1i1Uii#·ii1Mil1t-iidMii1..I Description: ROOF GRAVITY (BEAMS) Wood Beam Design : RB-1 Calculations per NDS 2018, IBC 2018, CBC 2019, ASCE 7-16 BEAM Size: 3.5x11.875, Parallam PSL, Fully Braced Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Wood Species : Trus Joist Wood Grade : Parallam PSL 2.0E Fb -Tension Fb -Compr 2,900.0 psi Fe -Prll 2,900.0 psi Fv 290.0 psi Ebend-xx 2,000.0 ksi Density 45.070 pcf 2,900.0 psi Fe -Perp 750.0 psi Ft 2,025.0 psi Eminbend -xx 1,016.54 ksi Applied Loads Beam self weight calculated and added to loads Unif Load: D = 0.020, Lr= 0.020 k/ft, Trib= 12.0 ft Design Summa,y Max fb/Fb Ratio = fb: Actual : Fb : Allowable : Load Comb: Max fv/FvRatio = fv: Actual: Fv : Allowable : Load Comb: 0.159; 1 575.36 ps, at 3,625.00 psi +D+Lr+H 0.148: 1 53.62 psi at 362.50 psi +D+Lr+H 4.000 ft in Span # 1 I 0.000 ft in Span # 1 8.0 ft Max Deflection$ · -· Max Reactions Left Support Right Support (k) Q 1 l.r 0.96 0.96 .s !:::! Transient Downward 0.023 in Total Downward 0.047 in 1.01 Ratio 4217>360 Ratio 2052 >240 1.01 Wood Beam Design : RB-2 Transient Upward Ratio LC: Lr Only 0.000 in 9999 LC: T otar Upward Ratio LC: +D+Lr+H 0.000 in 9999 LC: Calculations per NDS 2018, IBC 2018, CBC 2019, ASCE 7-16 BEAM Size: 5.25x11.875, Parallam PSL, Fully Braced ---- Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Wood Species : Trus Joist Wood Grade: Parallam PSL 2.0E Fb -Tension Fb -Compr 2900 psi Fe -Prll 2900 psi Fv 290 psi Ebend-xx 2000 ksi Density 45.07 pcf 2900 psi Fe -Perp 750 psi Ft 2025 psi Eminbend -xx 1016.535 ksi Applied Loads Beam self weight calculated and added to loads Unif Load: D = 0.020, Lr= 0.020 k/ft, Trib= 10.0 ft Design Summary Max fb/Fb Ratio = fb: Actual : Fb : Allowable : 0.276; 1 999.58 ps, at 7.000 ft in Span# 1 3,625.00 psi Load Comb: Max fv/FvRatio = fv: Actual: Fv : Allowable : Load Comb: +D+Lr+H 0.168: 1 60.76 psi at 13.020 ft in Span# 1 362.50 psi +D+Lr+H Max Reactions Left Support Right Support (k) Q L l.r 1.40 1.40 .s )fj_ 1.54 1.54 D(0.20) Lr(0.20) 5.25x11.875 14.0 ft Max Deflections · · .l:i Transient Downward 0.119in Total Downward 0.249 in 675 >240 Ratio 1416 >360 Ratio LC: Lr Only Transient Upward 0.000 in Ratio 9999 LC: Total Upward Ratio LC: +D+Lr+H 0.000 in 9999 LC: [ Multiple Simple Beam 131◄·M3!#Mtl•ln,w• Description: ROOF GRAVITY (HDR.) Wood Beam Design: RH-1 solidforms engineering Page 3 of 25 12/07/20 !1%1M►iilttl•4·li11&U1Hi,i@ii1J Calculations per NOS 2018, IBC 2018, CBC 2019, ASCE 7-16 BEAM Size: 6x6, Sawn, Fully Unbraced Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Douglas Fir -Larch Wood Grade : No.2 Wood Species : Fb -Tension Fb -Compr 875.0 psi Fe -Prll 600.0 psi Fv 170.0 psi Ebend-xx 875.0 psi Fe -Perp 625.0 psi Ft 425.0 psi Eminbend -xx 1,300.0 ksi 470.0ksi Density 31.210 pct Applied Loads Beam self weight calculated and added to loads Uni! Load: D = 0.020, Lr= 0.020 k/ft, Trib= 12.0 ft Design Summary Max fb/Fb Ratio fb: Actual: Fb : Allowable : Load Comb: 2.500 ft in Span # 1 Max fv/FvRatio = fv: Actual: Fv : Allowable : 0.602 · 1 658.00 psf at 1,093.75 psi +D+Lr+H 0.233: 1 49.46 psi at 212.50 psi +D+Lr+H 4.550 ft in Span # 1 I 6x6 5.0 ft Load Comb: , __ ~~~~ -=----------Max Defle"ciions Max Reactions Left Support Right Support (k) Q 1 0.62 h[ 0.60 0.60 'f:!. ti Transient Downward 0.034in Total Downward 0.069 in 864 >240 0.62 Wood Beam Design : RH-2 Ratio 1752 >360 Ratio Transient Upward Ratio LC: Lr Only 0.000 in 9999 LC: Total Upward Ratio LC: +D+Lr+H 0.000 in 9999 LC: Calculations per NOS 2018, IBC 2018, CBC 2019, ASCE 7-16 BEAM Size: Wood Species : 4x4, Sawn, Fully Unbraced Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Douglas Fir -Larch Wood Grade : No.2 Fb -Tension Fb -Compr 900 psi Fe -Prll 1350 psi Fv 180 psi Ebend-xx 900 psi Fe -Perp 625 psi Ft 575 psi Eminbend -xx Applied Loads Beam self weight calculated and added to loads Unif Load: D = 0.020, Lr= 0,020 k/ft, Trib= 8.0 ft Design Summary Max fb/Fb Ratio fb: Actual: Fb : Allowable : Load Comb: Max fv/FvRatio = fv: Actual: Fv : Allowable : Load Comb: 0.492 · 1 829.68 psi at 1,687.50 psi +D+Lr+H 0.258: 1 58.08 psi at 225.00 psi +D+Lr+H 1.750 ft in Span# 1 0.000 ft in Span # 1 Max Deflections 4x4 3.50 ft 1600 ksi 580 ksi Density 31.21 pcf Max Reactions Left Support Right Support (k) Q ~ W: 0.28 0.28 .5 Yi. Ii Transient Downward 0.027 in Total Downward 0.055 in 767 >240 0.28 0.28 Ratio Transient Upward Ratio 1547 >360 Ratio LC: Lr Only 0.000 in 9999 LC: Total Upward Ratio LC: +D+Lr+H 0.000 in 9999 LC: solidforms engineering Page 4 of 25 12/07/20 I Multiple Simple Beam 13i◄·M$'4•M•ltnm ➔1@,HB&i':'fii■,MhHiM·ii•@iid·I Wood Beam Design : RH-3 Calculations per NDS 2018, !BC 2018, CBC 2019, ASCE 7-16 BEAM Size: 4x10, Sawn, Fully Unbraced Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Wood Species : Trus Joist Wood Grade : Parallam PSL 2.0E Fb -Tension 2900 psi Fe -Prll 2900 psi Fv 290 psi Ebend-xx 2000 ksi Fb -Com pr 2900 psi Fe -Perp 750 psi Ft 2025 psi Eminbend -xx 1016.535 ksi Applied Loads Beam self weight calculated and added to loads Unif Load: D = 0.0160 k/ft, Trib= 9.0 ft Point: D = 1.60, Lr= 1.40 k@2.0 ft Design Summary Max fb/Fb Ratio fb: Actual: Fb : Allowable : Load Comb: Max fv/FvRatio = fv: Actual: Fv: Allowable : Load Comb: 79s°3~2p~f 1at 3,574.93 psi +D+Lr+H 0.216: 1 78.35 psi at 362.50 psi +D+Lr+H 2.000 ft in Span # 1 0.000 ft in Span # 1 --------pyfclx Deflections ---- Density Q 1 1r Yi. E .!:::1 Transient Downward 0.007 in Total Downward 1.11 0.70 Ratio 6836 >360 Ratio 45.07 pcf 0.017 in 2826 >240 Max Reactions (k) Left Support Right Support 1.11 0.70 LC: Lr Only LC: +O+Lr+H Transient Upward 0.000in Ratio 9999 LC: Total Upward Ratio 0.000 in 9999 LC: solidforms engineering Page 5 of 25 12/07/20 j Multiple Simple Beam 13i◄/83!t'4•13tlfiW• •13A11M►iiiiii••·li1Hil1HhM4ii,i•I Description: FLOOR GRAVITY (BEAMS) Wood Beam Design : FB-1 Calculations per NDS 2018, IBC 2018, CBC 2019, ASCE 7-16 BEAM Size: 5.25x14.0, Parallam PSL, Fully Braced Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Wood Species : Trus Joist Wood Grade: Parallam PSL 2.0E Fb -Tension Fb -Compr 2,900.0 psi Fe -Prll 2,900.0 psi Fv 290.0 psi Ebend-xx 2,000.0 ksi 2.900.0 psi Fe -Perp 750.0 psi Ft 2,025.0 psi Eminbend -xx 1,016.54 ksi Applied Loads Beam self weight calculated and added to loads Unit Load: D = 0.0140, L = 0.040 k/ft, Trib= 11.50 ft Unit Load: D = 0.0160 k/ft, Trib= 9.0 ft Unif Load: D = 0.020, Lr= 0.020 k/ft, Trib= 13.0 ft Desiga Summary Max lb/Fb Ratio = fb: Actual: Fb : Allowable : Load Comb: Max fv/FvRatio = fv: Actual: Fv : Allowable : Load Comb: 0.630; 1 1,796.58 psi at 2,850.80 psi +D+L+H 0.430: 1 124. 76 psi at 290.00 psi +D+L+H 7.000 ft in Span# 1 12.833 ft in Span # 1 Max D8flections 5.25x14.0 14.0 ft Density !:I Transient Downward 0.166in Total Downward Ratio 1009 >360 Ratio 45.070 pef 0.408 in 411 >240 Max Reactions Left Support Right Support (k) Q L 4.12 3.22 4.12 3.22 1I 1.82 1.82 LC: L Only 0.000 in 9999 LC: C: +D+0.750Lr+0.750L+H Wood Beam Design : FB-2 Transient Upward Ratio Total Upward O .000 in Ratio 9999 LC: Calculations per NDS 2018, IBC 2018, CBC 2019, ASCE 7-16 BEAM Size: 5.25x11.875, Parallam PSL, Fully Unbraced Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Wood Species : Trus Joist Wood Grade: Parallam PSL 2.0E Fb -Tension Fb -Compr 2900 psi Fe -Prll 2900 psi Fv 290 psi Ebend-xx 2000 ksi Density 45.07 pct 2900 psi Fe -Perp 750 psi Ft 2025 psi Eminbend -xx 1016.535 ksi Applied Loads Beam self weight calculated and added to loads Point: D = 3.60, Lr= 3.20 k@ 3.0 ft Design Summary Max fb/Fb Ratio = fb: Actual: Fb : Allowable : 0.319; 1 1, 142.26 psi at 3,575.37 psi +D+Lr+H 3.010 ft in Span# 1 I Load Comb: Max fv/FvRatio = fv: Actual: Fv : Allowable : Load Comb: 0.261 : 1 94.67 psi at 362.50 psi +D+Lr+H 0.000 ft in Span # 1 f L --~ax Defl8ctions 7.0 ft Max Reactions (k) Left Support Right Support Q L Lr 1.83 1.37 ll 'ti. ti. Transient Downward Ratio 0.026 in Total Downward 0.057 in 1479 >240 LC: +D+Lr+H 2.13 1.61 Transient Upward Ratio 3183 >360 Ratio LC: Lr Only 0.000 in 9999 LC: Total Upward Ratio 0.000 in 9999 LC: solidforms Page 6 of 25 12/07/20 engineering [ Multiple Simple Beam 13l◄·M3WM#lif:-tM• Wood Beam Design : FB-3 BEAM Size: !1341M►19llii#·liil"ia11-ihi@ii,i•' Calculations per NDS 2018, IBC 2018, CBC 2019, ASCE 7-16 7x14, Parallam PSL, Fully Braced Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Wood Species: Trus Joist Wood Grade: Parallam PSL 2.0E Fb -Tension 2,900.0 psi Fe -Prll 2,900.0 psi Fv 290.0 psi Ebend-xx 2,000.0 ksi Density 45.070 pcf Fb -Compr 2,900.0 psi Fe -Perp 750.0 psi Ft 2,025.0 psi Eminbend -xx 1,016.54 ksi Applied Loads Beam self weight calculated and added to loads Unif Load: D = 0.0140, L = 0.040 k/11, 0.0 ft to 8.0 ft, Trib= 11.50 ft Unif Load: D = 0.0140, L = 0.040 k/11, 8.0 to 15.50 ft, Trib= 6.0 ft Unif Load: D = 0.0140, L = 0.040 k/ft, 15.50 to 18.0 ft, Trib= 9.0 ft Unrr Load: D = 0.020, Lr= 0.020 k/11, 0.0 to 8.0 ft, Trib= 130 ft Point: 0=1.70, Lr=1.70k@0.50ft Point: D= 1.10, Lr= 1.0 k@8.0ft Point: D = 0.20, L = 0.20 k@11.50ft Point: 0=1.10, Lr=1.0k@15.50ft Point: D = 1.0, L = 0.40 k@ 15.50 ft Unif Load: D = 0.260, Lr= 0.260 k/11, 15.50 to 18.0 ft Unif Load: D = 0.1440 k/11, 0.0 to 18.0 ft Design Summary Max fb/Fb Ratio fb: Actual: Fb ; Allowable : Load Comb: Max fv/FvRatio = fv: Actual: 0. 731; 1 2,084.26 psi at 2,850.80 psi +D+L+H 7.980 ft in Span # 1 I 16.860 ft in Span# 1 7x14 18.0 ft Fv : Allowable ; Load Comb; 0.441 : 1 127.88 psi at 290.00 psi +D+L+H L_ __ Maxoet1ections _______ -------------- Max Reactions Left Support Right Support (k) Q L lJ 4.01 2.42 .s '!1. E. !:::! Transient Downward 0.272 in Total Downward 0.800 in 7.11 3.68 6.10 3.30 Ratio 794 >360 Ratio 270 >240 LC: L Only C: +D+0.750Lr+0.750L+H Transient Upward 0.000 in Total Upward 0.000 in Ratio 9999 Ratio 9999 LC: LC: Wood Beam Design : FB-4 Celculatlons per NDS 2018, IBC 2018, CBC 2019, ASCE 7-16 BEAM Size: 7x14, Parallam PSL, Fully Braced Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Wood Species : Trus Joist Wood Grade: Parallam PSL 2.0E Fb -Tension Fb -Compr 2900 psi Fe -Prll 2900 psi Fv 290 psi Ebend-xx 2000 ksi Density 45.07 pcf 2900 psi Fe -Perp 750 psi Ft 2025 psi Eminbend -xx 1016.535 ksi Applied Loads Beam self weight calculated and added to loads Unif Load: D = 0.0140, L = 0.040 k/11, Trib= 1.0 ft Unif Load: D = 0.0160 k/11, Trib= 9.0 ft Unif Load: D = 0.020, Lr= 0.020 k/11, Trib= 13.0 ft Point D = 1.70, Lr= 0.60 k@ 13.50 ft Design Summa,y Max fb/Fb Ratio = fb: Actual: Fb : Allowable : 0.569; 1 2,026.53 psi at 10.450 ft in Span # 1 1 3,563.50 psi Load Comb: Max fv/FvRatio = fv: Actual: Fv : Allowable : Load Comb: Max Reactions (k) Left Support Right Support +D+Lr+H 0.319: 1 115.69 psi at 17.860 ft in Span # 1 362.50 psi +D+Lr+H Q L 4.75 0.38 5.47 0.38 Lr 2.64 2.90 .s Yi ti 7x14 19.0 ft Max Deflections _____ ---------- Transient Downward 0.275 in Total Downward 0.790 in Ratio 828 >360 Ratio 288 >240 LC: Lr Only Transient Upward 0.000 in Ratio 9999 LC: Total Upward Ratio LC: +D+Lr+H 0.000 in 9999 LC: solidforms Page 7 of 25 12/07/20 engineering [ Multiple Simple Beam 151◄/MW?l:•l❖itilt• Wood Beam Design : FB-5 BEAM Size: 3.5x14.0, Parallam PSL, Fully Braced !MWi4►iilfti"'HiiH-l1i·!iil§§il1J Calculations per NOS 2018, IBC 2018, CBC 2019, ASCE 7-16 Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Wood Species: Trus Joist Wood Grade: Parallam PSL 2.0E Fb -Tension 2900 psi Fe-Prll 2900 psi Fv 290 psi Ebend-xx 2000ksi Density 45.07 pcf Fb -Com pr 2900 psi Fe -Perp 750 psi Ft 2025 psi Eminbend -xx 1016.535 ksi Applied Loads Beam self weight calculated and added lo loads Unif Load: D = 0.0140, L = 0.040 k/ft, Trib= 6.0 ft Unit Load: D = 0.0160 k/ft, Trib= 10.0 ft Unif Load: D = 0.020, Lr= 0.020 k/ft, Trib= 10.0 ft Design SummaO' Max fb/Fb Ratio = fb: Actual: 0.080; 1 229.37 psr at 2,850.80 psi +D+L+H 0.100: 1 28.90 psi at 290.00 psi +D+L+H 2.500 ft in Span # 1 Fb ; Allowable ; Load Comb: Max fv/FvRatio = fv: Actual: Fv : Allowable : Load Comb: Max Reactions Left Support Right Support (k) Q 1 1.15 0.60 1.15 0.60 1r 0.50 0.50 Wood Beam Design : FB-6 3.850 ft in Span # 1 'Ii BEAM Size: -3.5x14.0, Parallam PSL, Fully Braced ti Max Deflections Transient Downward Ratio 0.002 in Total Downward 0.007 in 8606 >240 9999 >360 Ratio LC: L Only C: +D+0.750Lr+0.750L+H Transient Upward 0.000 in Total Upward 0.000 in Ratio 9999 Ratio 9999 LC: LC: Calculations per NOS 2018, IBC 2018, CBC 2019, ASCE 7-16 ---------- Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Wood Species : Trus Joist Wood Grade : Paralfam PSL 2.0E Fb -Tension Fb -Compr 2,900.0 psi Fe -Prll 2,900.0 psi Fv 290.0 psi Ebend-xx 2,000.0 ksi Density 45.070 pct 2,900.0 psi Fe -Perp 750.0 psi Ft 2,025.0 psi Eminbend -xx 1,016.54 ksi Applied Loads Beam self weight calculated and added to loads Un, Load: D = 0.0160 k/ft, Trib= 10.0 ft Point: D = 1.20, Lr= 0.50, L = 0.60 k@ 11.50 ft Design Summa,y Max fb/Fb Ratio = fb; Actual: Fb : Allowable ; Load Comb: Max fv/FvRatio = fv: Actual: 77309~ 7 p~f 1at 8.000 ft in Span # 1 1 2,850.80 psi +D+L +H, LL Comb Run (•L) 0.233: 1 D(0.160) 3.5x14.0 3.50 ft Fv : Allowable: Load Comb: 67.69 psi at 8.000 ft in Span # 1 290.00 psi +D+L +H, LL Comb Run ("L) r L__ Max Deflections ----------·-----·---- Max Reactions (k) Left Support Right Support Q L Lr S 'Ii 0.04 -0.26 -0.22 3.17 0.86 0.72 E !:I. Transient Downward 0.030in Total Downward 0.103 in Ratio 2764 >360 Ratio 81 6 >240 L Only, LL Comb Run (•L) .0+0.750Lr+0.750L+H, LL Transient Upward -0.009 in Total Upward -0.027 in Ratio 9999 Ratio 3604 L Only, LL Comb Run (•L) -D+0.750Lr+0.750L+H, LL [ Multiple Simple Beam i!i◄•43W#•M•i~1'1tl• Wood Beam Design: FB-7 BEAM Size: 7x14, Parallam PSL, Fully Braced solidforms engineering Page 8 of 25 12/07/20 9134, m►m m "'"" 11" •,. • 11 ,14@ ,.. I Calculations per NDS 2018, IBC 2018, CBC 2019, ASCE 7-16 Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Wood Species : Trus Joist Wood Grade: Parallam PSL 2.0E Fb -Tension Fb -Comp, 2,900.0 psi Fe -Prll 2,900.0 psi Fv 290.0 psi Ebend-xx 2,000.0 ksi Density 45.070 pcf 2,900.0 psi Fe -Perp 750.0 psi Ft 2,025.0 psi Eminbend -xx 1,016.54 ksi Applied Loads Beam self weight calculated and added lo loads Unif Load: D = 0.0140, L = 0.040 klft, 0.0 ft lo 11.50 ft, Trib= 1.330 ft Point: D = 1.20, Lr= 0.50 k@ 19.50 ft Point D = 4.70, Lr= 220, L = 0.90 k@ 19.50 ft Design Summary Max lb/Fb Ratio 0.193 · 1 fb : Actual : 686.83 psf at 18.000 ft in Span # 1 Fb : Allowable : 3,563.50 psi Load Comb: +D+0.750Lr+0.750L+H, LL Comb Max fv/FvRatio = 0.366: 1 fv: Actual: 132.73 psi at 18.000 ft in Span# 1 Fv : Allowable : 362.50 psi Load Comb : +D+Lr+H, LL Comb Aun (*L) Max Reactions (k) .Q .!.. Lr .S W. .E Left Support -0.08 0.42 -0.22 Right Support 6.85 1.17 2.93 Wood Beam Design : FB-8 BEAM Size: l! Max Deflections 7x14 18.0 ft • ?x14 3.50 ft Transient Downward 0.051 in Total Downward 0.145 in Ratio 1652 >360 Ratio 580 >240 Lr Only, LL Comb Run (•L l+Lr+H, LL Comb Run (•L Transient Upward -0.046 in Total Upward -0.117 in Ratio 4723 Ratio 1854 Lr Only, LL Comb Run (•L l+Lr+H, LL Comb Run (•L Calculations per NDS 2018, IBC 2018, CBC 2019, ASCE 7-16 5.25x9.25, Parallam PSL, Fully Braced Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Wood Species : Trus Joist Wood Grade : Parallam PSL 2.0E Fb -Tension Fb -Compr 2900 psi Fe -Prlt 2900 psi Fv 290 psi Ebend-xx 2000 ksi 2900 psi Fe -Perp 750 psi Ft 2025 psi Eminbend -xx 1016.535 ksi Applied Loads Beam self weight calculated and added to loads Unif Load: D = 0.0160 k/ft, Trib= 3.50 ft Unif Load: D = 0.0340, L = 0.060 k/ft, 0.0 to 3.50 ft, Tnb= 5.0 ft Unif Load: D = 0.0340, L = 0.060 k/ft, 3.50 to 15.0 ft, Trib= 3.0 ft Design Summary Max fb/Fb Ratio fb: Actual: Fb : Allowable : Load Comb: Max fv/FvRatio = fv: Actual: Fv : Allowable : Load Comb: 1,685°a~8p1i 1at 2,900.00 psi +O+L+H 0.301 : 1 87.24 psi at 290.00 psi +O+L+H 7.300 ft in Span # 1 0.000 ft in Span # 1 0(0 170) L(0.30) ---Max Deflecti~ 5.25x9.25 15.0ft Density ll 1 Lr li 'fi. E l! Transient Downward Ratio 0.323in Total Downward 1.51 1.72 557 >360 Ratio 45.07 pcf 0.623 in 288 >240 Max Reactions (k) Left Support Right Support 1.33 1.40 LC: LOnly LC: +D+L+H Transient Upward 0.000 in Ratio 9999 LC: Total Upward Ratio 0.000 in 9999 LC: I Multiple Simple Beam t!i◄·P3WMd•it.fB31 Wood Beam Design : FB-9 BEAM Size: 7x14, Parallam PSL, Fully Braced solidforms engineering Page 9 of 25 12/07/20 9199eMB-1iWi••·ihM41i·ll11§§ll1J Calculations per NOS 2018, IBC 2018, CBC 2019, ASCE 7-16 Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Wood Species : Trus Joist Wood Grade : Parallam PSL 2.0E Fb -Tension 2900 psi Fe -Prll 2900 psi Fv 290 psi Ebend-xx 2000ksi Density 45.07 pcf Fb -Compr 2900 psi Fe -Perp 750 psi Ft 2025 psi Eminbend -xx 1016.535 ksi Applied Loads Beam self weight calculated and added to loads Unif Load: D = 0.0160 k/11, Trib= 10.0 ft Unif Load: D = 0.0140, L = 0.040 k/ft, Tnb= 2.0 ft Unif Load: D = 0.020, Lr= 0.020 k/11, Trib= 10.0 ft Design summa,y Max fb/Fb Ratio = fb: Actual: Fb : Allowable : 0.560; 1 1,995.99 psi at 11.000 ft in Span # 1 3,563.50 psi Load Comb: Max fv/FvRalio = fv: Actual: Fv : Allowable : Load Comb: +D+0.750Lr+0.750L+H 0.263: 1 95.26 psi at 0.000 ft in Span # 1 362.50 psi +D+0. 750Lr+0. 750L+H Max Reactions Left Support Right Support (k)Q 1 l.r ll Yi 4.61 0.88 2.20 4.61 0.88 2.20 !:! -Max OeflectTons Transient Downward Ratio 7x14 22 .0 ft 0.331 in Total Downward 1.041 in 797 >360 Ratio 253 >240 LC: Lr Only C: +D+0.750Lr+0.750L+H Transient Upward 0.000 in Total Upward 0.000 in Ratio 9999 Ratio 9999 LC: LC: I Multiple Simple Beam 131◄·831'Mfltltk4rl• Description: FLOOR GRAVITY (HDR.) Wood Beam Design : FH-1 BEAM Size: 4x8, Sawn, Fully Unbraced solidforms engineering Page 10 of 25 12/07/20 !134rH4►iilfti•#·li11&Uhi-iid99iirl·' Calculations per NDS 2018, IBC 2018, CBC 2019, ASCE 7-16 Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Wood Species : Douglas Fir -Larch Wood Grade : No.2 Fb -Tension Fb -Compr 900.0 psi Fe -Prll 1,350.0 psi Fv 180.0 psi Ebend-xx 1,600.0 ksi 580.0 ksi Density 31.21 o pct 900.0 psi Fe -Perp 625.0 psi Ft 575.0 psi Eminbend -xx Applied Loads Beam self weighl calculaled and added to loads Unif Load: D = 0.0140, L = 0.040 k/ft, Trib= 11.0 ft Unif Load: D = 0.0160 k/ft, Trib= 10.0 ft Unit Load: D = 0.020, Lr= 0.020 k/11, Trib= 11.0 ft Design Summa,y Max fb/Fb Ratio fb: Actual: Fb : Allowable : 0.370-1 431.27 psf at 1,165.38 psi +D+L+H 1.500 ft in Span # 1 Load Comb: Max fv/FvRatio = fv: Actual: Fv : Allowable : Load Comb: 0.290: 1 52.11 psi at 180.00 psi +D+L+H Max Reactions Left Support Right Support (k) ll 1 1r 0.33 0.33 0.81 0.66 0.81 0.66 Wood Beam Design : FH-2 2.400 ft in Span # 1 ll Yi. f; jj BEAM Size: 5.25x14.0, Parallam PSL, Fully Unbraced -Max DefleCtTo-nS- Transient Downward Ratio 0.005 in Total Downward 0.011 in 7941 >360 Ratio 3377 >240 LC: L Only C: +D+0.750Lr+0.750L+H Transient Upward 0.000 in Total Upward 0.000 in Ratio 9999 Ratio 9999 LC: LC: Calculations per NDS 2018, IBC 2018, CBC 2019, ASCE 7-16 Wood Species : Using Allowable Stress Design with ASCE 7·16 Load Combinations, Major Axis Bending Trus Joist Wood Grade : Parallam PSL 2.0E Fb • Tension Fb -Compr Applied Loads 2,900.0 psi Fe -Prll 2,900.0 psi Fv 290.0 psi Ebend-xx 2,000.0 ksi 2,900.0 psi Fe • Perp 750.0 psi Ft 2,025.0 psi Eminbend • xx 1,016.54 ksi Beam self weight calculaled and added to loads Unit Load: D = 0.0140, L = 0.040 k/ft, Trib= 10.0 ft Design Summary Max fb/Fb Ratio tb: Actual: Fb : Allowable : Load Comb: Max fv/FvRatio = fv: Actual: Fv : Allowable : Load Comb: 0.458 · 1 1,260.60 psf at 2,753.53 psi +D+L+H 0.273: 1 79.05 psi at 290.00 psi +D+L+H 8.000 ft in Span # 1 0.000 ft in Span # 1 5.25x14.0 16.0 ft Density (k) Q L Lr li Yi. jj Max Deflections Transient Downward Ratio 0.247in Total Downward 1.30 3.20 777 >360 Ratio 45.070 pct 0.348 in 552 >240 Max Reactions Left Support Right Support 1.30 3.20 LC: LOnly 0.000 in 9999 LC:+D+L+H Transient Upward Ratio LC: Total Upward Ratio 0.000 in 9999 LC: [ Multiple Simple Beam l31◄·■3Utld•iV..f4d• Wood Beam Design : FH-3 BEAM Size: 6x6, Sawn, Fully Unbraced solid forms engineering Page 11 of 25 12/07/20 !1941MB-1iWii#·li11"U1i•ii,i§§•ht·' Calculatlons per NOS 2018, IBC 2018, CBC 2019, ASCE 7-16 Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Wood Species : Douglas F'1r • Larch Wood Grade : No.2 Fb -Tension Fb -Compr 875 psi Fe -Prll 600 psi Fv 170 psi Ebend-xx 1300ksi 470 ksi Density 31.21 pct 875 psi Fe -Perp 625 psi Ft 425 psi Eminbend -xx Applied Loads Beam self weight calculated and added to loads Unif Load: D = 0.0160 klft, Trib= 10.0 ft Unif Load: D = 0.0340, L = 0.060 k/ft, Tnb= 3.0 ft Design Summary Max fb/Fb Ratio = fb: Actual: Fb : Allowable : 0_250; 1 218.38 psi at 875.00 psi +D+L+H 0.137: 1 23.35 psi at 170.00 psi +D+L+H 1.500 ft in Span # 1 Load Comb: Max fv/FvRatio = fv: Actual: Fv: Allowable : Load Comb: Max Reactions Left Support Right Support (k) Q I. 0.40 0.27 0.40 0.27 1r Wood Beam Design : FH-4 2.550 ft in Span # 1 ll Yi --~eflections .,. 3.0 ft .l:i Transient Downward Ratio 0.003 in Total Downward 0.008 in 4342 >240 9999 ,360 Ratio LC: LOnly Transient Upward 0.000 in Ratio 9999 LC: Total Upward Ratio LC: +D+L+H 0.000 in 9999 LC: Calculations per NOS 2018, IBC 2018, CBC 2019, ASCE 7-16 BEAM Size: 3.5x11.25, Parallam PSL, Fully Unbraced Using Allowable Stress Design with ASCE 7-16 Load Combinations, Major Axis Bending Wood Species : Trus Joist Wood Grade: Parallam PSL 2.0E Fb -Tension Fb -Compr 2900 psi Fe -Prtl 2900 psi Fv 290 psi Ebend-xx 2000 ksi Density 45.07 pct 2900 psi Fe -Perp 750 psi Ft 2025 psi Eminbend -xx 1016.535 ksi Applied Loads Beam self weight calculated and added to loads Point: D = 10.60, Lr= 5.20, L = 3.70 k@ 1.50 ft Design Summary Max fb/Fb Ratio = fb: Actual: Fb : Allowable: Load Comb: Max fv/FvRatio = fv: Actual: Fv : Allowable : Load Comb: 0.608; 1 1,745.49 psi at 2,872.56 psi +D+L+H 0-940: 1 272.65 psi at 290.00 psi +D+L+H ll L Max Reactions (k) Left Support Right Support 5.32 1.85 Lr 2.60 2.60 5.32 1.85 1 .500 ft in Span # 1 2.070 ft in Span # 1 .s 'Ii_ ---Max Deflections .1::i Transient Downward Ratio 0.006 in Total Downward 0.020 in 5886 >360 Ratio 1 769 >240 LC: Lr Only C: +D+0.750Lr+0.750L+H Transient Upward O.OOOin Total Upward 0.000 in Ratio 9999 Ratio 9999 LC: LC: Seismic Design solidforms engineering Page 12 of 25 12/07/20 Design Variables Base Shear Calculation (ASCE 7-16 Sec. 12.8 & Supplement 2) Latitude= 33.16 (12.8·2) V=CsW Cs= Sos*I/R Longitude= -117.33 Site Class= D (12.8·3) Where: Cs ma,. = for HT,, 501 *!/{RT) Occupancy= II Table 1.5-1 (12.8-4) forT>T,, So1*T,*I/{RT2) Seis. category = D Table 11.6-1 & 2 I= 1.0 Tables 1-1 & 11.s-1 (12.8·5) Where: Cs m;,. = for s,<0.6:0.044505!~0.0l R= 6.5 Table 12.2-1 (12.8-6) for s,ao.6, 0.551*1/R s, = 1.038 Section 11.4.1 51 = 0.377 Section 11.4.1 DL Area Len. Fa= 1.200 Table 11.4-1 Material (psf) (ft') (ft) fv = 1.923 Table 11.4-2 Load 2 16 1400 SMs = Ss*F, = 1.246 ~ -(11.4-1) ~~ SMl = S1*fv = 0.725 (11.4-2) C. QJ Ext. Wall 1 16 155 ::::, _, Sos = 2/3*5Ms = 0.830 (11.4·3) Int. Wall 7 70 501 = 2/3*5Ml = 0.483 (11.4·4) 1400 All other structural systems Table 12.8-2 C, = 0.02 Table 12.8-2 w Load 1 14 1200 6i x= 0.75 Table 12.8-2 _, Load 3 14 1230 ~ T, = 8 Figure 22-15 ~ Load 4 34 110 T, = C,*h: = 0.189 (12.8-7) _g Ext. Wall 1 16 210 T= T, = 0.189 Section 12.8.2 Int. Wall 7 100 2540 h, = 20.0 Section 12.8.2.1 Cs= 0.128 Section 12.8.1.1 k= 1 Section 12.8.3 Ca= 4 Table 12.2-1 ti,, = h * "' 0.025 Table 12.12-1 Vertical Distribution of Forces & Allowable Elastic Drift (ASCE 7-16, Sec. 12.8.3 & 12.8.6) Level ___ Wx hx h." Wxhx" Fx Fx (psi) % p 1i,e alk>w. Upper Level 37.3 20.0 20.0 745 7.4 5.3 69% Yes 0.825 Lower Level 68.9 9.0 9.0 620 6.2 2.4 100% Yes 0.675 106.1 1365 14 8 Level Forces (ASCE 7-16, Sec. 12.10.1.1) Level w. :t:w. F, :t:F, Fox Fpx (ASD) Where: Roof 37.3 37.3 7.4 7.4 7.4 5.2 Fm;,.= 0.21SosW, Lower Level 68.9 106.1 6.2 13.6 11.4 8.0 Fma,. = 0.41505W, 106.1 13.6 Ht. (ft) 10 10 8 8 = 0.128 0.393 Max. = 0.037 Min. Above w (kips) (kips) 22.4 12.4 2.5 37.3 16.8 17.2 3.7 12.4 + 13.4 2.5 + 2.8 68.9 Where: 1i,e alk>w. = Ii,, *1/C., (Section 12.8.6) p : Redundancy Check Required if story shear is > 35% of base shear (Section 12.3.4.2) Wind Design solidforms engineering Page 13 of 25 12/07/20 Wind Pressures for MWFRS ASCE 7-16 -Envelope Procdedure Method 2 Design Variables Occupancy= Iwind = Basic Wind Speed (mph)= Exposure Category = Topographic K,, = Width (ft)= Length (ft) = Roof Pitch Eave Ht. (ft) = Ridge Ht. (ft) = Mean Roof Ht (ft) = >. = 8= >.K,,I = 2a (ft) = Min. Design Load (psf) = II 1.00 110 B 1 23.0 55.0 Flat 19.0 19.0 19.0 1 0.0 1.0 11.0 16.0 Table 1.5-1 Tables 1.5-2 Figure 26.5-lA Section 26.7.3 Section 26.8.2 Transverse Longitudinal Figure 28.6-1 Figure 28.6-1 Note 9 Section 28.4.4 p, = >.K,,Ip530 (28.6-1) Note:(-) Horiz. Pressures shall be zero. Horiz. Press. Vert. Press. Overhangs __ _ -A ---B---C---D E F G H -E=C~H~ GCH (psf) Transverse Longitudinal 19.2 -10.0 12.7 -5.9 -23.1 -13.1 -16.0 -10.1 -32.3 -25.3 19.2 --1-0.-0 _1_2_.7_ -5.~9-~-2=3-.1---1-3-.l,---1~6~.0----1-0-.l--32.3 -25.3 -------------------1 >+------Width, W= ---i-Rid • Eave hei~ height Wind pressures are In psf •e~ wind pr....-.:e is t.ss than zero (0), un O for dasign. Transverse Governing Design Force: Transverse Tributary Area: Transverse Governing Design Pressure: 16.7 kips 1045 ft2 16.0 psf Wind pressures are in psf Longitudinal Governing Design Force: Longitudinal Tributary Area: Longitudinal Governing Design Pressure: 7.0 kips 437 ft2 16.0 psf Transverse Zone Ps Area Force (k) Total (I<)_ A 19.2 209 4.0 ------ B 0.0 0 0.0 14.6 C 12.7 836 10.6 D 0.0 0 0 Min. 16.0 1045 16.7 16.7 ------------------- E -23.1 127 -2.9 F -13.1 127 -1.7 -17.8 G -16.0 506 -8.1 ---- H -10.1 506 -5.1 Min. -16.0 1265 -20.2 -20.2 Lonaitudinal Zone Ps Area Force (k) Total (k) A 19.2 209 4.0 ------- B 6.9 ---- C 12.7 228 2.9 D Min. 16.0 437 7.0 7.0 ------------ E -23.1 303 -7.0 F -13.1 303 -4.0 -19.6 G -16.0 330 -5.3 ------------- H -10.1 330 -3.3 Min. -16.0 1265 -20.2 -20.2 Lateral Design Upper Level N-S Line: Seis. Area (tt') = 500 Shear Line Len.Tot (ft) = 22 Wind Relative to Ridge_= __ P_e~rpe_nd_i_cu_la_r_ Wind Lengths: Left Right li< = Vert.Trib Height (ft) = 5.0 -----,---¼ = Dist to Adj Gridline (ft) = 20.0 Shear Above: Line = L v.,.,.. (Seis/Wind) = °lornb. of Load = vxAbv.Trib. (Seis/Wind) = solidforms engineering A p = 1.0 Sos= 0.830 Plate Ht. (ft) = 10 lw,mt. (ft) = Perforated Shearwall Strength Design Seis. Force: F x = Maximum Wind Pressure: Px = vxSeis.(ASD) = Area/2*Fx*P*0.7 = V-,,:w100 = LH*Lw/2*Px*0.6 = IV, (Above) = VKTotal = See Perforated Shearwall Cales on Following Pages Upper Level N-S Line: Seis. Area (tt') = 1200 Shear Line Len.Tot (ft) = 22 ___ w~,~·n~d-'--'Relative to Ridge = Parallel I Wind Lengths: Left Right li< = Vert.Trib Height (ft) = I 5.0 __ __, __ _ L. = Dist to Adj Gridline (ft) = I 55.0 Shear Above: Line = v,,,.""' (Seis/Wind) = %Trib. of Load = '-------VxAbv.Trib. (Seis/Wind) = ____ _ C p = 1.0 Sos= 0.830 Plate Ht. (ft) = 10 lw,rn,. (ft) = 10 Shearwall Strength Design Seis. Force: Fx = Maximum Wind Pressure: Px = vxSets(ASD) = Area/2*Fx*P*0.7 = VxWirKJ = LH*lw/2*Px*D.6 = IV, (Above) = VK Total = Vx/L = Use Sheaiwall Type= with LTP4 clips@ - Seis. Wind 5.3 16.0 925 480 925 480 0 Seis. Wind 5.3 16.0 2220 1320 2220 1320 222 132 @ 48 "o.c. psf psf lbs lbs lbs lbs psf psf lbs lbs lbs lbs plf Page 14 of 25 12/07/20 60% for entire length of grid line C Wooc Sheaiwalls = Length = Load Type= Shear Load (lbs) = Wall DLD,st (psf) = Resis. DLo,.. (plf) = Resis. Dleo,,, (lbs) = DLp,,,,, Dist (ft) = MomentoT (lb-ft) = 'Moment,,,,,._ (lb-ft) = Uplift (lbs) = Uplift,"°""= Uplift.«. = Left Holdown = Right Holdown = w, 10 Seis._ I Wind 2220 1320 7 22200 13200 1693 2100 2159 1168 2159 1168 Per Plan Per Plan w, I 0 - - - - w, w, I I 0 0 0 0 0 ----- ----- ----- ---- 1Resisting Moment DL is reduced by 0.6-0.14*Sos for Seis.(12.14.3.1.3) & 0.6 for Wind (2.4.1) Ws w, I I -0 0 0 0 ---- -- ---- ---- Lateral Design Upper Level Seis. Area (fl') = Shear Line Len.,ot (ft) = Wind Relative to Ridge = Wind Lengths: N-S Line: 750 21 Perpendicular Left Right 5.0 Li< = Vert.Trib Height (ft)= -----+---, solidforms engineering G p = 1.0 Sos= 0.830 Plate Ht. (ft) = 10 lwau Tot. (ft) = Perforated Shearwall Strength Design Seis. Force: Fx = Maximum Wind Pressure: Px = VKSeis.(ASO) = Area/2*F x *p*0.7 = v-.Wird = 4i*Lw/2*Px*0,6 = 'DI, (Above) = L. = Dist to Adj Gridline (ft) = 35.0 ---~--~---------~ Vx Toti!I = Shear Above: Line = v,_. (Seis/Wind) = %re,. of Load = vxAbv.Tnb. (Seis/Wind) = ~---See Perforated Shearwall Cales on Following Pages Upper Level E-W Line: 1-2 Perforated Shearwall Seis. Area (fl') = 1400 Strength Design Seis. Force: fx = Shear Line Len.rot. (ft) = 50 p= 1.0 Maximum Wind Pressure: Px = Wind Relative to Ridge= Parallel Sos= 0.830 VxSeis.(ASD) = Area/2*F .. *p*0.7 = Wind Lengths: Left Right Plate Ht. (ft) = 10 V.x.wioo = LH*Lw/2*Px*0,6 = Lt< = Vert.Trib Height (ft) = 5.0 lwan Tot. (ft) = 'DI, (Above) = L. = Dist to Adj Gridline (ft) = 20.0 Vx Total = Shear Above: Line= v,_. (Seis/Wind) = o/o-rnb. of Load = VxAbv.rnb. (Seis/Wind) = See Perforated Shearwall Cales on Following Page---,---~- 1Resisting Moment DL is reduced by 0.6-0.14*Sos for Seis.(12.14.3.1.3) & 0.6 for Wind (2.4.1) Seis. Wind 5.3 16.0 1387 840 1387 840 0 Seis. Wind 5.3 16.0 2590 480 2590 480 0 psf psf lbs lbs lbs lbs psf psf lbs lbs lbs lbs Page 15 of 25 12/07/20 Lateral Design Upper Level E·W Line: Seis. Area (ft') = 2600 Shear Line Len.Toe (ft) = SO Wind Relative to Ridge= Parallel Wind Lengths: Left Right ~ = Vert.Trib Height (ft) = I 5.0 ---+---' Lw = Dist to Adj Gridline (ft) = I 20.0 Shear Above: Line = L_ v,,_ (Seis/Wind) = o/o-rnb. of Load = Vl<Abv.Trlb. (Seis/Wind) = Wood Shearwalls = Length = Load Type= Shear Load (lbs) = Wall DL0,._ (psf) = Resis. Dlo,sc (plf) = Resis. Dl.e.ot (lbs) = DLPoint Dist (ft) = MomentoT (lb-ft) = 1Moment:,.,,sc (lb-ft) = Uplift (lbs) = Uplift,,,,.., = Uplift.et. = Left Holdown = Right Holdown = W1 20 Seis. I Wind 2405 240 16 140 24050 2400 29025 36000 -255 -1723 N/A N/A Lower Level N·S Line: Seis. Area (ft') = 500 Shear Line Len.rot (ft) = 12 ___ W_ind Rela_tiv_e_t_o_R_id~g~e_= ___ P_a_ra_ll_el_~ Wind Lengths: Left Right ~ = Vert.Trib Height (ft) = I 9.0 ---+--~ solidforms engineering 6 p = 1.0 Sos= 0.830 Plate Ht. (ft) = 10 l.w,11 Tot. (ft) = 40 Shearwall Strength Design Seis. Force: fx = Maximum Wind Pressure: Px = VKSeis (ASO) = Area/2*F x *p*0.7 = VxWind = LH*lw/2*Px *0.6 = IV, (Above) = Vx Total = VxfL= Use Shearwall Type= with LTP4 clips@ Seis. Wind 5.3 16.0 4810 480 4810 480 120 12 @ 48 "o.c. for entire length of grid line 6 w, 20 Seis. I Wind 2405 240 16 140 24050 2400 29025 36000 -255 -1723 N/A N/A Al-6 p = 1.0 Sos= 0.830 Plate Ht. (ft) = 8 Lwan Tot. (ft) = 12 0 - - - - w, w, w, I I I 0 0 0 0 0 0 ------ ------ ----------- ---i --- Shearwall Seis. Wind Strength Design Seis. Force: F x = 2.4 Maximum Wind Pressure: Px = 16.0 VKSe,s(ASDJ = Area/2*Fx*p*0.7 = 424 VK'Nind = LH*Lw/2*Px *0.6 = 864 IV, (Above) = 925 480 1349 1344 Lw = Dist to Adj Gridline (ft) = I 20.0 ----~----+--~-----------VxTotal = Shear Above: Line = Upper Level A ~-- v,,_ (Seis/Wind) = 925 480 0/o-rnb. of Load = 100% vxAbv.Trib. (Seis/Wind) = 925 480 Wood Shearwalls = Length = Load Type= Shear Load (lbs) = Wall DL0,._ (psf) = Resis. Dlo,sc (plf) = Resis. DI.,,,,,, (lbs) = DLPoint Dist (It) = Momentc,T (lb-ft) = 1Moment:,.,1s, (lb-ft) = Uplift (lbs) = Uplift,oa,, = Uplift.et. = Left Holdown = Right Holdown = W1 12 Seis. I 1349 16 10792 4458 551 N/A Wind 1344 10752 5530 454 N/A w, j 0 0 0 ---- --- --------·-·· --- --- Vx/L = 112 112 Use Shearwall Type= @ with LTP4 clips@ 48 "o.c. for entire length of grid line Al-6 w, w, w, I I I 0 0 0 0 0 0 ------ ------ ------ -----I - 1Resisting Moment DL is reduced by 0.6-0.14"5os for Seis.(12.14.3.1.3) & 0.6 for Wind (2.4.1) psf psf lbs lbs lbs lbs plf Page 16 of 25 12/07/20 57% w, I 0 - - - I - psf psf lbs lbs lbs lbs plf 67% w, I 0 - - - I - Lateral Design Lower Level N-S Line: Seis. Area (ft') = 1200 Shear Line Len.Tot. (ft) = 20 Wind Relative to Ridge = Perpendicular Wind Lengths: 4i = Vert.Trib Height (ft) = I.,. = Dist to Adj Gridline (ft) = Shear Above: Line= v..,_,._ (Seis/Wind) = 0/oi-r1b. of Load = V ><Abv.Tnb. (Seis/Wind) = Wood Shearwalls = Length= Load Type= Shear Load (lbs) = Wall D4list. (psf) = Resis. Dloist. (plf) = Resis. D4'oint (lbs) = D4>oint Dist (ft) = Momentor (lb-ft) = 1Momen4!eslst. (lb-ft) = Uplift (lbs) = Upli~= Upli~= Left Holdown = Right Holdown = Lower Level Seis. Area (ft') = Shear Line Len.Tot. (ft) = Wind Relative to Ridge = Wind Lengths: 4i = Vert.Trib Height (ft) = I.,. = Dist to Adj Gridline (ft) = Shear Above: Line= v..,_,._ (Seis/Wind) = o/o,-r1b. of Load = v><Abv.Trlb. (Seis/Wind) = Wood Shearwalls = Length= Load Type= Shear Load (lbs) = Wall Dlo;st. (psf) = Resis. Dlo;st. (plf) = Resis. D4>oint (lbs) = D4>oint Dist (ft) = Momentor (lb-ft) = 1Momen~st (lb-ft) = Uplift (lbs) = Upli~= Upli~= Left Right I 9.0 I 50.0 . . . W1 12 Seis. I Wind 1018 2160 16 8142 17280 4458 5530 320 1022 320 1022 Per Plan Per Plan N-S Line: 650 10 Parallel Left Right I 9.0 I 30.0 Upper Level C 2220 1320 100% 2220 1320 W1 7.5 Seis. I Wind 2771 2616 7 22170 20928 762 945 3058 2855 3058 2855 Left Holdown = Per Plan Right Holdown = Per Plan solidforms Page 17 of 25 12/07/20 engineeri ng A6-9 p = 1.0 Sos= 0.830 Plate Ht. (ft) = 8 Lwan Tot. (ft) = 12 . . . W2 I 0 0 . . . . . . . . C p = 1.0 Sos= 0.830 Plate Ht. (ft) = 8 lwanot. (ft)= 7.5 . . . W2 I 0 0 . . . . . . . . . 0 . . . . . 0 - . . . Shearwall Seis. Wind Strength Design Seis. Force: F, = 2.4 psf 16,0 psf lbs 2160 lbs lbs . W3 I Maximum Wind Pressure: P, = VXSeisCASOl = Area/2*F,*p*0.7 = 1018 ><Wir>l = lti*lw/2*P, *0.6 = V rv. (Above) = 1018 2160 lbs 85 180 plf . Use Shearwall Type= @ with LTP4 clips@ 48 "o.c. 64% for entire length of grid line A6·9 w~ Ws w6 I I I 0 0 0 0 0 0 0 . . . . . . . . . . -. . . . . . -. . . . . . . . . . Shearwall Wind Strength Design Seis. Force: F, = Seis. 2.4 psf psf lbs lbs lbs lbs plf . W3 I Maximum Wind Pressure: P, = V.s,;s.(ASOl = Area/2*F,*p*0.7 = xWlr>l = lti*Lw/2*P,*0.6 = V . rv, (Above) = V,TOClll = VJ L = Use Shearwall Type= 16.0 551 1296 2220 1320 2771 2616 369 349 @ with LTP4 clips@ 16 "o.c. 55% for entire length of grid line C w~ Ws w6 I I I 0 0 0 0 0 0 0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 'Resisting Moment DL Is reduced by 0.6-0.l◄*Scs for Sels.(12.1◄.3.1.3) &. 0.6 for Wind (2.◄.l) Lateral Design Lower Level Seis. Area (ft') = Shear Line Len.Tot. (ft) = Wind Relative to Ridge = Wind Lengths: I.ti = Vert.Trib Height (ft) = I.,., = Dist to Adj Gridline (ft) = Shear Above: Line= v_ (Seis/Wlnd) = 0/oi-rib. of Load = v-..AtN.Trlb. (Sels/Wlnd) = Wood Shearwalls = Length= Load Type = Shear Load (lbs) = Wall Dlo;s1. (psf) = Resis. Dlo;s1. (plf) = Resls. D4'1>int (lbs) = D4'olnt Dist (ft) = Momentcrr (lb-ft) = 1Momen41esist. (lb-ft) = Uplift (lbs) = Upll~= Upli~ = Left Holdown = Right Holdown = N-S Line: 750 22 Parallel Left Right I 9.0 I 33.0 - -- W1 3.5 Seis. I Wind 636 1426 16 5089 11405 379 470 1570 3645 1570 3645 Per Plan Per Plan Lower Level N-S Line: Sets. Area (ft') = 1020 Shear Line Len.Tot. (ft) = 12 Wind Relative to Ridge = Wind Lengths: I.ti = Vert.Trib Height (ft) = I.,., = Dist to Adj Grldline (ft) = Shear Above: Line = v_ (Seis/Wind) = o/oi-nb. of Load = v-..AtN.Trtb. (Seis/Wind) = Wood Shearwalls = Length= Load Type = Shear Load (lbs) = Wall Dlo;st (psf) = Resls. Dlo;st. (plf) = Resis. D4'olnt (lbs) = D4'olnt Dist (ft) = Momentcrr (lb-ft) = 1Momen~st (lb-ft) = Uplift (lbs) = Upli~= Upli~= Parallel Left Right I 9.0 I 50.0 - -- W1 8 Seis. I Wind 865 2160 7 4200 2 6921 17280 4930 6115 265 1489 265 1489 Left Holdown = Per Plan Right Holdown = Per Plan solid forms Page 18 of 25 12/07/20 en gi neeri n g D p = 1.0 Sos = 0.830 Plate Ht. (ft) = 8 Lwa11 Tot. (ft) = 3.5 - --- W2 I 0 0 0 --- --- --- --- E p = 1.0 Sos= 0.830 Plate Ht. (ft) = 8 Lwall Tot. (ft) = 8 - --- W2 I 0 0 0 --- --- --- --- Shearwall Wind Strength Design Sels. Force: F, = Seis. 2.4 psf 16.0 psf lbs 1426 lbs lbs - W3 I Maximum Wind Pressure: P, = Vl<Sels(ASO) = Area/2*F,*p*0.7 = XWlnd = 1..ti*Lw/2*P, *0.6 = V Bl. (Above) = 636 v,Toc:a1 = 636 1426 lbs 3.5:1 = (h/2L)* Vx/L = 208 407 plf -@ Use Shearwall Type= with L TP4 clips @ 48 "o.c. 39% for entire length of grid line D W4 Ws W5 I I I 0 0 0 0 0 0 0 ------- ------- ------- ------- Shearwall Seis. Wind Strength Design Sels. Force: F, = 2.4 psf 16.0 psf lbs 2160 lbs lbs - W3 I Maximum Wind Pressure: P, = Vl<Sels.(ASO) = Area/2*F.*p*0.7 = 865 XWlnd = Ltt*Lw/2*P.*0.6 = V Bl, (Above) = V,Total = 865 2160 lbs Vx/L = 108 270 plf -@ Use Shearwall Type= with LTP4 dips@ 24 "o.c. 54% for entire length of grid line E W4 Ws W5 I I I 0 0 0 0 0 0 0 ------- ------- ------- ------- 'Resisting Moment DL Is reduced by 0.6-0.14*S.,. for Sels.(12.14.3.1.3) & 0.6 for Wind (2.4.1) Lateral Design Lower Level Seis. Area (fr) = Shear Line Len.Tot. (ft) = Wind Relative to Ridge = Wind Lengths: 1..+i = Vert.Trib Height (ft) = L.. = Dist to Adj Gridline (ft) = Shear Above: Line = v,_ (Seis/Wind) = o/ornb. of Load = vxAbv.Trtb. (Seis/Wind) = Wood Shearwalls = Length = Load Type = Shear Load (lbs) = Wall Dlast. (psf) = Resis. Dlast. (plf) = Resis. D4>oint (lbs) = D4>oint Dist (ft) = Momentor (lb-ft) = 1Momen~ (lb-ft)= Uplift (lbs) = Upli~= Upli~. = Left Holdown = Right Holdown = N-S Line: 400 8 Parallel Left Right I 9.0 I 19.0 - -- W1 8 Seis. I Wind 339 821 16 2714 6566 1981 2458 98 548 N/A N/A Lower Level N-S Line: Seis. Area (fr) = 650 Shear Line Len.Tot. (ft) = 20 Wind Relative to Ridge = Wind Lengths: 1..+i = Vert.Trib Height (ft) = L.. = Dist to Adj Gridline (ft) = Shear Above: Line = v,_ (Seis/Wind) = %,-rib. of Load = VxAbv.Trtb. (Seis/Wind) = Wood Shearwalls = Length = Load Type= Shear Load (lbs) = Wall DLOist. (psf) = Resis. Dlast. (plf) = Resis. D4>oint (lbs) = D4>oint Dist (ft) = Momentor (lb-ft) = 1Momen~st. (lb-ft) = Uplift (lbs) = Upli~= Upli~= Parallel Left Right I 9.0 I 3o.o Upper Level G 1387 840 100% 1387 840 W1 5 Seis. I Wind 1939 2136 16 15510 17088 774 960 3275 3584 3275 3584 Left Holdown = Per Plan Right Holdown = Per Plan solidforms Page 19 of 25 12/07/20 engineeri n g F p = 1.0 Sos= 0.830 Plate Ht. (ft) = 8 Lwall Tot. (ft) = 8 - -- W2 I 0 0 -- -- -- -- G p = 1.0 Sos= 0.830 Plate Ht. (ft) = 8 lwaH Tot. (ft) = 5 - -- W2 I 0 0 -- -- -- -- - 0 - - - - - 0 - - - - - Shearwall Strength Design Seis. Force: F. = Maximum Wind Pressure: Px = VJCSeis(ASO) = Area/2*F.*p*0.7 = XWlnd = l+i*Lw/2*P. *0.6 = V - r.v. (Above) = Vx Total = VJL = Use Shearwall Type= Seis. 2.4 339 Wind psf 16.0 psf lbs 821 lbs lbs 339 821 lbs 42 103 plf @ with LTP4 clips @ 48 "o.c. 61% for entire length of grid line F W3 W4 Ws w6 I - I I I 0 0 0 0 0 0 ------ ------ ------ ------ Shearwall Seis. Wind Strength Design Seis. Force: F. = 2.4 Maximum Wind Pressure: P. = psf 16.0 psf Vx5e15 <ASOJ = Area/2*F. *p*0. 7 = 551 lbs V xWind = l..+i*Lw/2*P.*0.6 = 1296 lbs r.v. (Above) = 1387 840 lbs v. Total = 1939 2136 lbs VJ L = 388 427 plf -@ Use Shearwall Type= 0 - - - - with L TP4 d ips @ 48 "o.c. 64% for entire length of grid line G W3 W4 Ws w6 I I I I 0 0 0 0 0 0 0 ------- ------- ------- ------- 'Resisting Moment DL Is reduced by 0.6-0.14*S.,. for Sels.(12.14.3.1.3) &. 0.6 for Wind (2.4.1) Lateral Design Lower Level Seis. Area (tt2) = Shear Line Len.rat. (ft) = Wind Relative to Ridge = Wind Lengths: ltt = Vert.Trib Height (ft) = I.,. = Dist to Adj Gridline (ft) = Shear Above: Line= v._ (Seis/Wind} = %rrtb. of Load = vl<Abv.Trtb. (Seis/Wind) = E-W Line: 660 23 Parallel Left Right I 9.0 I 23.0 Upper Level 1-2 2590 480 100% 2590 480 solid forms engineering 1 p = 1.0 Sos= 0.830 Plate Ht. (ft) = 8 lwan Tat. (ft) = Perforated Shearwall Strength Design Seis. Force: F, = Maximum Wind Pressure: P. = V>CSes (ASO) = Area/2*F • *p*0. 7 = XWJnd = Ltt*Lw/2*P,*0.6 = V '[)I, (Above) = Seis. 2.4 560 2590 Wind psf 16.0 psf lbs 994 lbs 480 lbs V,ro1a1 = 3150 1474 lbs -- ----0 Page 20 of 25 12/07/20 See Perforated Shearwall Cales on Following Pages Lower Level Seis. Area (tt2) = Shear Line Len.rot (ft) = Wind Relative to Ridge = Wind Lengths: ltt = Vert.Trib Height (ft) = I.,. = Dist to Adj Gridline (ft) = Shear Above: Line = v._ (Seis/Wind} = o/orrtb. of Load = vl<Abv.Trtb. (Seis/Wind) = Wood Shearwalls = Length= Load Type= Shear Load (lbs) = Wall Dlo;st. (psf) = Resis. Dlo;st. (plf) = Resis. D4'0int (lbs) = D4'0int Dist (ft) = Momentor (lb-ft) = 1Momen41esist. (lb-ft) = Uplift (lbs) = Uplitt_ = Upli~ = E-W Line: 570 20 Parallel Left Right I 9.0 I 20.0 Upper Level 1-2 2590 480 100% 1060 480 W1 3.5 Seis. I Wind 1543 1344 16 12344 10752 379 470 3988 3427 3988 3427 Left Holdown = Per Plan Right Holdown = Per Plan 3 p = 1.0 Sos= 0.830 Plate Ht. (ft) = 8 Lw,11 rat. (ft) = 3.5 - -- W2 I 0 0 -- -- -- -- - 0 - - - - - Shearwall Strength Design Seis. Force: F. = Maximum Wind Pressure: P, = V>CSes(ASOJ = Area/2*F.*p*0.7 = XWJnd = ltt*Lw/2*P• *0.6 = V '[)I, (Above) = Seis. 2.4 483 1060 Wind psf 16.0 psf lbs 864 lbs 480 lbs v. ro1a1 = 1543 1344 lbs 3.5: 1 = (h/2L}* V.,/L = 504 384 plf - Use Shearwall Type= @ with L TP4 clips @ 32 "o.c. 31% for entire length of grid line 3 W3 W4 Ws w6 I I I I 0 0 0 0 0 0 0 ------- ------- ------- ------- 'Resisting Moment DL Is reduced by 0.6-0.14*S,,. for Sels.(12.14.3.1.3) & 0.6 for Wind (2.4.1) Lateral Design Lower Level Seis. Area (ft2) = Shear Line Len.rot (ft) = Wind Relative to Ridge = Wind Lengths: 4i = Vert.Trib Height (ft) = lw = Dist to Adj Gridline (ft) = Shear Above: Line = v,_ (Seis/Wind) = °lornb. of Load = VxNN.rnb. (Seis/Wind) = Wood Shearwalls = Length= Load Type = Shear Load (lbs) = Wall Dloist. (psf) = Resis. Dlo;s1. (plf) = Resis. DLp.,;nt (lbs) = DLp.,;nt Dist (ft) = Momentor (lb-ft) = 1Momen41es;s1. (lb-ft) = Uplift (lbs) = Upl i~ = Upli~ = Left Holdown = Right Holdown = Seis. Area (ft2) = Shear Line Len.rot (ft) = Wind Relative to Ridge = Wind Lengths: 4i = Vert.Trib Height (ft) = Lw = Dist to Adj Gridline (ft) = Shear Above: Line= v,_ (Seis/Wind) = °lornb. of Load = VxNN.Tnb. (Seis/Wind) = Wood Shearwalls = on Concrete = Load Type= Shear Load (lbs) = Wall Dlo;st_ (psf) = Resis. Dl..o;st. (plf) = Resis. DLp.,;nt (lbs) = D4>oint Dist (ft) = Momentor (lb-ft) = E-W Line: 1220 18 Parallel Left Right I 9.o I 21.0 Upper Level 6 4810 480 100% 4810 480 W1 18 Seis. I Wind 5845 1387 16 140 46757 11098 21002 26050 1472 -854 1472 N/A Per Plan Per Plan Line: I I - -- W1 I solidforms engineering 5 p = 1.0 Sos= 0.830 Plate Ht. (ft) = 8 I.wall Tot (ft) = 18 -- --- Sheaiwall Seis. Strength Design Seis. Force: F. = 2.4 Maximum Wind Pressure: P. = V>CSels(ASOJ = Area/2*F.*p*0.7 = 1035 xW!nd = 1.+i*Lw/2*P,*0.6 = V 'I.V. (Above) = 4810 Wind psf 16.0 psf lbs 907 lbs 480 lbs v. roto1 = 5845 1387 lbs VJ L = 325 77 plf - Use Shearwall Type= @ Page 21 of 25 12/07/20 with L TP4 clips @ 16 "o.c. 65% W2 I 0 0 0 --- --- --- --- p = 1.0 Sos= 0.830 Plate Ht. (ft) = lwoll Tot. (ft) = - --- W2 I for entire length of grid line 5 W3 W4 Ws w6 I I I I 0 0 0 0 0 0 ------ ------ ------ ------ Sheaiwall Seis. Wind Strength Design Seis. Force: F. = psf psf lbs lbs lbs lbs plf - W3 I Maximum Wind Pressure: Px = VxS<is(ASOJ = Area/2*F.*p*0.7 = xWlnd = l.+i*lw/2*P,*0.6 = V - 'I.Vx (Above) = VxTotol = VJ L = Use Shearwall Type= with LTP4 clips@ for entire length of grid line W4 Ws I I 0 6 "o.c. w6 I 0 - - - - 1Momen41esist. (lb-ft) = 1----+---+---+----+---+---+----+----+---+----+---r--U p Ii ft (lbs) = Upli~= Upli~= Left Holdown = Right Holdown = 1ResisUng Moment DL Is reduced by 0.6-0.14*Scs for Sels.(12.14.3.1.3) & 0.6 for Wind (2.4.1) Lateral Design Lower Level Seis. Area (ft') = Shear Line Len.Tot. (ft) = Wind Relative to Ridge = Wind Lengths: Ltt = Vert.Trib Height (ft) = Lw = Dist to Adj Gridline (ft) = Shear Above: Line = v_ (Seis/Wind) = o/ornb. of Load = v>IAbv.Tnb. (Seis/Wind) = E-W Line: 1400 12 Parallel Lett Right I 9.0 I 30.0 - -- solidforms en gin eeri n g 9 p = 1.0 Sos= 0.830 Plate Ht. (ft) = 8 lwoll Tct. (ft) = - -- - - Perforated Sheaiwall Seis. Strength Design Seis. Force: F. = 2.4 Maximum Wind Pressure: P. = VxSels.(ASOl = Area/2*F,*p*0.7 = 1187 XWlnd = ltt*Lw/2*P, *0.6 = V rv. (Above) = Wind psf 16.0 psf lbs 1296 lbs lbs V,Tctol = 1187 1296 lbs -0 See Perforated Sheaiwall Celc:s on Following Pages Seis. Area (ft') = Shear Line Len.Tot. (ft) = Wind Relative to Ridge = Wind Lengths: ltt = Vert.Trib Height (ft) = Lw = Dist to Adj Gridline (ft) = Shear Above: Line = v_ (Seis/Wind) = 0/orrib. of Load = v>IAbv.Trib. (Seis/Wind) = Wood Shearwalls = Length= Load Type = Shear Load (lbs) = Wall Dlo;st. (psf) = Resis. Dlo;st. (plf) = Resis. D4'olnt (lbs) = Lett - Line: Right I I - - W1 I p = 1.0 Sos = 0.830 Plate Ht. (ft) = Lw.11 Tct. (ft) = - -- Wz I - - Sheaiwall Strength Design Seis. Force: F, = Maximum Wind Pressure: P, = VxSels.(ASOl = Area/2*F, *p*0.7 = .winc1 = ltt*Lw/2*P, *0.6 = V - rv, (Above) = V,Tctal = V.,/L = Use Shearwall Type= with LTP4 dips@ Seis. Wind 0 48 "o.c. for entire length of grid line W3 w~ Ws I I I psf psf lbs lbs lbs lbs pit w6 I Page 22 of 25 12/07/20 D4>o1n1 Dist (ft) = 1---~--f--~----i---.----+----.-----+----.----+---,---~ Momentor (lb-ft) = 1Momen~st. (lb-ft) = 1---~----+----+----+---+---~----+----+---+---+----,1----U p Ii ft (lbs) = Uplitt_= Upli~ = Left Holdown = Right Holdown = 'Resisting Moment DL Is reduced by 0.6-0.14*Sos for sets.(12.14.3.1.3) &. 0.6 for Wind (2.4.1) Perforated Shear Wall Analysis so lid forms eng in eering Page 23 of 25 12/07/20 Wood Framed Shear Walls with Openings (SEAOC Design Manual Vol. II} Gov. Grid Line: Upper Level A Force: Seismic = Sos = 0.8304 Uniformly Distributed Resisting DL = Wall Dimensions (ft} W1 W2 W3 Window 2 5 2 Hl = 1 H2 = 2 H3 = 7 9 ft Max Shear = 925 lbs 144 plf I !Oft Overturning Moment = 1Resist. Overturning Moment = Resulting Uplift Force = Header Strap Tension = Sill Strap Tension = 231 plf 9250 lbs*ft 2821 lbs*ft 714 lbs 514 lbs 294 lbs Holdown Per Plan CS16 Strap 30% CS16 Strap 17% 'Resisting Moment DL Is reduced by 0.&-0.11•5os for Sels.(12.11.3.1.3) &. 0.6 for Wind (2.1.1) Gov. Grid Line: Upper Level G Force: Seismic = S05 = 0.8304 Uniformly Distributed Resisting DL = Wall Dimensions (ft) W1 W2 W3 Window 3.5 6.5 7 ,------------------, Hl = 1 ............................... H2 = S H3 = 4 17 ft Max Shear = 286 plf €} Overturning Moment = 13875 lbs*ft 1Resist. Overturning Force = 10066 lbs*ft Resulting Uplift Force = 224 lbs N/A Header Strap Tension = 928 lbs CS16 Strap Sill Strap Tension = 431 lbs CS16 Strap 1387 lbs 144 plf 1'·· 54% 25% 1Reslstlng Moment DL Is reduced by 0.6-0.11*Sos for Seis.(12.11.3.1.3) &. 0.6 for Wind (2.1.1) Vert. Shear Force Above Header 1 206 1 ,---_,,Header Strap Tensio .... n ----. V (lb) =I (51) I I 514 I I (51) Shear t bove Jenin~ v (plf) =I (26) I 206 l__illLJ Horiz. Force@ Openi~ V(lb)=I 462 I ~ .----, Shear @ Opening .----, v (plf) =I 231 I I 231 Vert. Shear Force Below Sill T (lb)= I 822 1 V (lb) =I 169 Sill jtrap Teron I 294 I 169 Shear Below Sill V (plf) =I 84 I 117 I 84 Vert. Shear Force T (lb) =I 1028 I 1 -1028 1 Vert. Shear Force Above Header 1 286 1 Header Strap Tension V (lb) =,-1 (-37-7)--,1 I 928 I .-, -(9-2)--, Shear t bove o1enin~ v (plf) =I (108) I 286 L@_J Horiz. Force @ Openi~ V (lb) =I 551 I ~ ,----, Shear @ Opening ,----, v (plf) =I 157 I I 120 Vert. Shear Force Below Sill T (lb)= 1 s31 1 V (lb) =I 120 Sill r rap Teran 1 431 1 406 Shear Below Sill V (plf) =I 34 I 133 I 58 Vert. Shear Force T (lb) =I 816 I -816 solid forms e ngi neering Gov. Grid Une: Upper Level 1-2 Force: Seismic= S05 = 0.8304 Uniformly Distributed Resisting DL = Wall Dimensions (ft) W1 W2 W3 Window 2.5 16.S 2.5 Hl = 2 H2 = HJ = 5 3 Max Shear = Overturning Moment = 1Resist. Overturning Force = Resulting Uplift Force = Header Strap Tension = Sill Strap Tension = 21.5 ft 330 plf 16482 lbs*ft 16100 lbs*ft 18 lbs 1423 lbs 1159 lbs N/A CS16 Strap CS16 Strap 1648 lbs 144 plf 83% 68% 1Reslstlng Moment DL Is reduced by 0.6-0.14*S,,, l'or Sels.(12.14.3.1.3) &. 0.6 fOf Wind (2.4.1) Gov. Grid Line: Lower Level 1 Force: Seismic = Sos= 0.8304 Uniformly Distributed Resisting DL = Wall Dimensions (ft) W1 W2 W3 Window 2.5 6.5 3 1861 lbs 144 plf :: : : ,-:::-:::-::::-::::-:::-::::-:::-::::-:::,--------,-------, I , . Max Shear = Overturning Moment = 1Resist. Overturning Force = Resulting Uplift Force = Header Strap Tension = Sill Strap Tension = 12 ft 543 plf 16751 lbs*ft 5015 lbs*ft 978 lbs 1764 lbs 924 lbs @} N/A Dbl CS16 CS16 Strap 52% 54% 1Reslsting Moment DL Is reduced by 0.6-0.14*S,,, l'or Sels.(12.14.3.1.3) &. 0.6 fOf Wind (2.4.1) Gov. Grid Une: Lower Level 9 Force: Seismic= Sos = 0.8304 Uniformly Distributed Resisting DL = Wall Dimensions (ft) W1 W2 W3 Window 2.5 6.5 2.5 Hl = 1 ............................... H2 = 5 ............................... HJ = 2 11.5 ft Max Shear = 361 plf ~ Overturning Moment = 9499 lbs*ft 1Resist. Overturning Moment = 4606 lbs*ft Resulting Uplift Force = 425 lbs N/A Header Strap Tension =· 1174 lbs CS16 Strap Sill Strap Tension = 755 lbs CS16 Strap 1187 lbs 144 plf 69% 44% Page 24 of 25 12/07/20 Vert. Shear Force Above Header 1 345 1 Header Strap Tension V (lb) = ,-1 ..,..(5--99_,,.)-,I I 1423 I I,-..,..(5--99.,..,.)-,l ~-_,Shear Above Openinf,I...__., v (plf) =I (240) i l 172 ! L..QiQlJ ~----'H...;..;oriz. Force @ Openi~ V (lb) =I 824 I ~ ~--. Shear @ Opening ~--. v (plf) =I 330 l I 330 Vert. Shear Force Below Sill T (lb) = I 422 l Sill jtrap TeTion V (lb) =-I -(3-35-)-,i 1159 ~I (-33-5)-i Shear Below Sill v (plf) =I (134) i l 141 i I (134) I Vert. Shear Force T (lb) = ,-l -7-67---,i ,-l -_ 7_6_7 _, Vert. Shear Force Above Header 1 543 1 Header Strap Tension V (lb) =Ir--(8-7-2)-,i l 1764 I ,.--(7-95-)-,i Shear Above Openin~ V (plf) =r-I ..,...(3-49_,,)-,i I 543 ! WillJ Horiz. Force @ Openi~ V (lb) =,-l """5=9,,....2-,i ~ ~--, Shear @ Opening ~--. v (plf) =I 357 I l 323 Vert. Shear Force Below Sill T (lb}= I 853 I V (lb) =I (32) Sill jtrap TeTion I 924 I 45 Shear Below Sill V (plf) =I (13) I 284 I 15 Vert. Shear Force T (lb) =I 1396 I I -1396 I Vert. Shear Force Above Header 1 361 I ~-_,Header Strap Tensio_n ----, V (lb) =I (581) I I 1174 I l (581) l Shear t bove 1enin~ v (plf) =I,--(2-32_,,.)-,l 361 ~ Horiz. Force@ Openi~ V (lb) = ,-1 """5--94--,i LJ21-J Shear @ Opening V (plf) = ,-1 -=2=3=7 _,, ,-l -=2=3=7-, Vert. Shear Force Below Sill T (lb) = l 465 i Sill jtrap TeTion V (lb) =,-1 -(1_6_1)-,i 755 l~(l_6_1)-,i Shear Below Sill v (plf) =I (65) i I 232 i l (65) i Vert. Shear Force T (lb) =l,-....,8..,...26--,I ,-1 --8--2-6-, solidforms engineeri n g Page 25 of 25 12/07/20 Foundation Design Concentrated Loads Pad Ftg: Fl q= 1500 psf D( 6900 )+Lr( 3000 )+L( 1200 ) + W( ) + E( ) = 11,100 # Total Load Gov. Load: D+0.75L+0.75Lr = 10050 # Factored Load .../(144* 10050 / 1500 )= 31.1 11 Min. Square Dimension Use: 33 "Sqr. x 18 "Deep with (4) #5 Bars Ea. Way Loaded:■:g@ Pad Ftg: F2 q= 1500 psf D( 4700 )+Lr( 2200 )+L( 900 ) + W( ) + E( ) = 7,800 # Total Load Gov. Load: D+0.75L+0.75Lr = 7025 # Factored Load .../(144* 7025 / 1500 )= 26.0 11 Min. Square Dimension Use: 30 "Sqr. x 18 "Deep with (4) #5 Bars Ea. Way Loaded:fifl Pad Ftg: Fl q= 1500 psf D( 11400 )+Lr( 9000 )+L( 7000 ) + W( ) + E( ) = 27,400 # Total Load Gov. Load: D+0.75L+0.75Lr = 23400 # Factored Load .../(144* 23400 / 1500 )= 47.4 11 Min. Square Dimension Use: 51 "Sqr. X 18 "Deep with (6) #5 Bars Ea. Way Loaded: ■:fM Pad Ftg: F4 q= 1500 psf D( 5500 )+Lr( 2900 )+L( 400 ) + W( ) + E( ) = 8,800 # Total Load Gov. Load: D+Lr = 8400 # Factored Load .../(144* 8400 I 1500 )= 28.4 11 Min. Square Dimension Use: 33 "Sqr. X 18 "Deep with (4) #5 Bars Ea. Way Loaded:@M ,.-,-.---------------------------------------. DevelCJpfllent _Services ( City of Carlsbad PURPOSE CLIMATE ACTION PLAN CONSISTENCY CHECKLIST B-50 Building Division 1635 Faraday Avenue (760) 602-2719 www.carlsbadca.gov This checklist is intended to assist building permit applicants identify which Climate Action Plan (CAP) ordinance requirements apply to their projects. The completed checklist must be included in the building permit application. It may be necessary to supplement the completed checklist with supporting materials, calculations or certifications, to demonstrate full compliance with CAP ordinance requirements. For example, projects that propose or require a performance approach to comply with energy-related measures will need to attach to this checklist separate calculations and documentation as specified by the ordinances. NOTE: The following type of penmits are not required to fill out this form ❖ Patio I ❖ Decks I ❖ PME (w/o panel upgrade) I ❖ Pool A If an item in the checklist is deemed to be not applicable to a project, or is less than the minimum required by ordinance, an explanation must be provided to the satisfaction of the Building Official. A Details on CAP ordinance requirements are available on the city's website. A A CAP Building Plan template (form B-55) shall be added to the title page all building plans. This template shall be completed to demonstrate project compliance with the CAP ordinances. Refer to the building application webpage and download the latest form. Project Name/Building Permit No.: _____________ BP No.: 'Pc2o2o -Q02( Property Address/APN: 205-130-59-00 Applicant Name/Co.: David Geesey ---------------------------------- App Ii cant Address: 1640 Sandalwood Lane, Carlsbad, CA 92008 Contact Phone: 760-707-391 O Contact Email: Safari123089@gmail.com Contact information of person completing this checklist (if different than above): Name: Company name/address: Applicant Signature: ~ .,/ T B-50 Contact Phone: Contact Email: Date: 12/11/2020 Page 1 of 6 Revised 06/18 Ci(y of Carlsbad Climate Action Plan Consistency Checklist Use the table below to determine which sections of the Ordinance Compliance checklist are applicable to your project. For alterations and additions to existing buildings, attach Building Permit Valuation worksheet. Building Permit Valuation (BPV) from worksheet: $ 2Ca4 ro'J [!] Residential □ New construction □ Additions and alterations: □ BPV < $60,000 □ BPV;, $60,000 □ Electrical service panel upgrade only µ:j BPV;, $200,000 D Nonresidential □ New construction □ Alterations: □ BPV;, $200,000 or additions;, 1,000 square feet □ BPV;, $1,000,000 □ ;, 2,000 sq. ft. new roof addition 1. Energy Efficiency Low-rise N/A 1A,4A ~1A, 4A,:J High-rise I1B, 2B, 3B,4A N/A 4A 1B,4A' 1 B, 2B, 3B, 4B and 5 1B, 5 1B, 2B, 5 2B,5 A high-rise residential building is 4 or more stories, including a mixed-use building in which at least 20% of its conditioned floor area is residential use All residential additions and alterations 1-2 family dwellings and townhouses with attached garages only 'Multi-family dwellings only where interior finishes are removed and significant site work and upgrades to structural and mechanical, electrical, and/or plumbing systems are proposed Building alterations of;, 75% existing gross floor area 1B also applies if BPV;, $200,000 Please refer to Carlsbad Municipal Code (CMC) sections 18.21.155 and 18.30.190, and the California Green Building Standards Code (CALGreen) for more infom,ation when completing this section. A Residential addition or alteration~ $60,000 building pennit valuation. 0 N/A ________ _ CMC section 18.30.190. D Exception: Home energy score~ 7 (attach certification) Year Built Single-family Requirements Multi-family Requirements Pf( Before 1978 Select one: □Duct sealino l!I Attic insulation □ Cool roof □ Attic insulation □ 1978 and later Select one: □ Lighting package □Water heating Package □ Between 1978 and 1991 Select one: □ Duct sealing □Attic insulation □Cool roof □ 1992 and later Select one: □Lighting package □Water heating package B. D Nonresidential' new construction or alterations~ $200,000 building permit valuation, or additions ~ 1,000 square feet □ N/A lJ pdatcd 8/ I 5/2019 2 C!,ty of Carlsbad Climate Action Plan Consistency Checklist See CMC 18.21.155 and CALGreen Appendix AS, Division AS.2-Energy Efficiency. AS.203.1.1 Choose one: Cl .1 Outdoor lighting □.2 Warehouse dock seal doors Cl .3 Restaurant service water heating (comply with California Energy Code section 140.5, as amended) □ N/A _________ _ □ .4 Da~ight design PAFs □.s Exhaust air heat recovery A5.203.1.2.1 Choose one as applicable: 095 Energy budget 090 Energy budget □ NIA A5.211.1tt D On-srte renewable energy □ NIA A5.211.3tt D Green power (if offered by local utility provider, 50% minimum renewable souroes) □ NIA A5.212.1 D Elevators and escalators □ NIA AS.213.1 D Steel framing □ NIA 'Includes hotels/motels and high-nse residential buildings tt For alterations~ $1,000,000 BPV and affecting > 75% existing gross floor area, or alterations that add 2,000 square feet of new roof addition: comp~ wrth CMG 18.30.130 instead. 2. Photovoltaic Systems A. D Residential new construction (for low-rise residential building penrnit applications submitted after 1/1/20). Refer to 2019 California Energy Code section 150.1(c)14 for requirements. Notes: 1) High-rise residential buildings are subject to nonresidential photovoltaic requirement (28 below) instead. 2) ~ project includes installation of an electric heat pump water heater pursuantto CMC 18.30.150(8) (high-rise residential) or 18.30.170(8) (low-rise residential), increase system size by .3kWdc if PV offset option is selected. Floor Plan ID (use additional CFA #d.u. Calculated kWdc' sheets if necessary) Total System Size: kWdc= (CFAx.572) / 1,000 + (1.15x#d.u.) 'Fonrnula calculation wihere CFA = conditional floor area, #du= number of dwellings per plan type If proposed system size is less than calculated size, please explain. Exception □ □ □ □ kWdc B. D Nonresidential new construction or alterations ~$1,000,000 BPV and affecting ?75% existing floor area, or addition that increases roof area by ?2,000 square feet Please refer to CMC section 18.30.130 when completing this section. Note: This section also applies to high-rise residential and hoteUmotel buildings. Choose one of the following methods: □ Gross Floor Area (GFA) Method GFA: 011 < 10,000s.f. Enter: 5 kWdc Min. System Size: 011;, 10,000s.f. calculate: 15 kWdc x (GFA/10,000) •• kWdc **Round building size factor to nearest tenth, and round system size to nearest whole number. □ Time-Dependent Valuation Method Updated 8/15/2019 3 ~ity of Carlsbad Climate Action Plan Consistency Checklist Annual TDV Energy use:• .. ______ x .80= Min. system size: _____ kWdc ... Attach calculation documentation using modeling software approved by the California Energy Commission. 3. Water Heating A. D Residential and hotel/motel new construction Please refer to CMC sections 18.30.150 and 18.30.170 when completing this section. O For systems serving individual dwelling units choose one: D Heat pump water heater AND Compact hot water distribution AND Drain water heat recovery (low-rise residential only) D Heat pump water heater AND PV system .3 kWdc larger than required in CMC section 18.30.130 (high rise residential hotel/motel) or CA Energy Code section 150.1{c) 14 {low-rise residential) D Heat pump water heater meeting NEEA Advanced Water Heating Specification Tier 3 or higher D Solar water heating system that is either .60 solar savings fraction or 40 s.f. solar collectors 0 Exception: O For systems serving multiple dwelling units, install a central water-heating system with all of the following: 0 Gas or propane water heating system O Recirculation system per CMC 18.30.150(8) (high-rise residential, hotel/motel) or CMC 18.30.170(8) (low- rise residential) D Solar water heating system that is either: D .20 solar savings fraction D .15 solar savings fraction, plus drain water heat recovery 0 Exception: 8. D Nonresidential new construction Please refer to Carlsbad Ordinance CMC section 18.30,150 when completing this section. O Water heating system derives at least 40% of its energy from one of the following (attach documentation): D Solar-thermal D Photovoltaics D Recovered energy □Water heating system is (choose one): □ Heat pump water heater □ Electric resistance water heater(s) □Solar water heating system with .40 solar savings fraction 0 Exception: Updated 8/15/2019 4 City o_f Carlsbad Climate Action Plan Consistency Checklist 4. Electric Vehicle Charging A ~esidential New construction and major alterations• Please refer to Carlsbad Ordinance CMC section 18.21.140 when com ne and two-family residential dwelling or townhouse with attached garage: f}one EVSE Ready parking space required .@-Exceptio11 . tlel Requi,ed 0 Multi-family residential· D Exception · Total Parking Spaces EVSESoaces Proposed Caaable Readv Installed Calculations: Total EVSE spaces= .10 x Total parking (rounded up to nearest whole number) EVSE Installed= Total EVSE Spaces x .50 (rounded up to nearest whole number) EVSE other= Total EVSE spaces -EVSE Installed (EVSE other may be "Capable," "Ready" or "Installed.") Total *Major alterations are: (1) for one and two-family dwellings and townhouses with attached garages, alterations have a building perm~ valuation~ $60,000 or include an electrical service panel upgrade; (2) for multifamily dwellings (three units or more without attached garages), alterations have a building permit valuation~ $200,000, interior finishes are removed and significant site work and upgrades to structural and mechanical, electrical, and/or plumbing systems are proposed. B D Nonresidential new construction (includes hotels/motels) D Exception · Total Parking Spaces EVSE Soaces Proposed Capable Ready Installed Total Calculation· Refer to the table below· Total Numberof Park·1rm Spaces provided Number of reauired EV Spaces Number of reauired EVSE Installed Spaces □ 0-9 1 1 □ 10-25 2 1 □ 26-50 4 2 □ 51-75 6 3 □ 76-100 9 5 □ 101-150 12 6 □ 151-200 17 9 11 201 and over 10 n,arcent of total 50 nercent of Reauired EV Spaces Updated 8/15/2019 5 City o_f Carlsbad Climate Action Plan Consistency Checklist 5. D Transportation Demand Management (TDM): Nonresidential ONLY An approved Transportation Demand Management (TOM) Plan is required for all nonresidential projects that meet a threshold of employee-generated ADT. City staff will use the table below based on your submitted plans to determine whether or nor your permit requires a TOM plan. IITDM is applicable to your permit, staff will contact the applicant to develop a site-specific TOM plan based on the permtt details. Acknowledgment: •-Employee ADT Estimation for Various Commercial Uses Use EmpADTfor first 1,000 s.f. EmpADTI 1000 s.f., Office (all), 20 Restaurant 11 Retaib 8 Industrial 4 Manufacturing 4 Warehousin 4 1 Unless otherwise noted, rates estimated from /TE Trip Generation Manual, 10'"Edition 13 11 4.5 3.5 3 1 2 For all office uses, use SAN DAG rate of 20 ADT/1,000 sf to calculate employee ADT 3 Retail uses include shopping center, variety store, supermarket, gyms, pharmacy, etc. Other commercial uses may be subject to special consideration Sample calculations: Office 20,450 sf 1. 20,450 sf/ 1000 x 20 = 409 Employee ADT Retail: 9,334 sf 1. First 1,000 sf= 8 ADT 2. 9,334 sf -1,000 sf= 8,334 sf 3. 8,334 sf/ 1,000 x 4.5 + 8 = 46 Em lo ee ADT I acknowledge that the plans submrtted may be subject to the City of Carlsbad's Transportation Demand Management Ordinance. I agree to be contacted should my permit require a TOM p~d understand that an approved TOM plan is a condttion of permit issuance. Applicant Signature \d.-/ =7 Date 12/11/2020 Person other than Applicant to be contacted for TDM compliance (if applicable): Name(Printed): __________________ _ Phone Number. ____ _ Email Address·. __________________ _ lJ pdated 8115/2019 6 GJr_.,j) -PCj''l20-0051 . . https://mail.google.com/mail/u/O?ik=6al l ffi276f&view=pt&search& ... I of9 .--. Gmail David & Beth Geesey <safari123089@gmail.com> PC2020-0051 Jason Pasiut <Jason.Pasiul@carlsbadc.gov> Tue, Jan 19, 2021 at 8:39 AM To: David & Beth Geesey <Safari123089@grnaU.com> Cc: Shay Even <Shay.Even@car1sbadca.gov>, Building <buHding@carlsbadca.gov> Good morning, I will approve the proposed design after there-submittal is reviewed by your Esgil Plan Examiner. Please have the Plan Examiner reach out to me when they are conducting the review. Thank you ( City of Carlsbad Jason Pasiut Building and Code Enforcement Manager I Building Community Development Department 1635 Faraday Ave. Carlsbad, CA 92008 www.carlsbadca.gov 760-602-27881 760-720-8558 fax I Jason.pasiut@carlsbadca.gov Facebook I Twitter I You Tube I Pinterest IEnews From: David & Beth Geesey <safari123089@gmail.com> Sent: Friday, January 15, 2021 7:03 PM To: Jason Pasiut <Jason.Pasiut@carlsbadca.gov> Cc: Shay Even <Shay.Even@carlsbadca.gov>; Building <building@CarlsbadCA.gov> Subject: Re: FW: PC2020-0051 Jason- 2/11/2021, 8:19 PM Gmail -P(jl020-005 I ht1ps://mail.google.com/mail/u/O?ik=6al lffi276f&view=pt&searc& ... . . . 2of9 Please let me clarify. I'm not seeking to use my neighbo(s soils report because they do not have one. Instead, they improved their standard foundation to mitigate any adverse soils conditions. (See attached) My building engineer has increased the size of footings and slab thickness, provided additional soils notes on the plans and classified the soi as silty sand. I've attached his updated drawings and correction letter, both dated 21-01-12. I would like to follow the precedence your department approved for my neighbor. Please confirm this is acceptable. Thank you -David Geesey On Fri, Jan 15, 2021 at 10:00 AM Shay Even <Shay.Even@carlsbadca.gov> wrote: 2/11/2021, 8:19 PM ( City of Carlsbad HOUSING DEVELOPMENT TRACKING Development Services Planning Division 1635 Faraday Avenue (760) 602-4610 www.carlsbadca.gov P-20 The following infonnation is required by to the Slate of California to track new housing development for all inrome levels. Please complete this form to the best of your knowledge and submit prior to building permit i$$U311c:e. Project Name: Geesey ADU Tract/Permit No.: ---=-------------Project Address: 1640 Sandalwood Lane, Carlsbad, CA 92008 APN: 205-130-59-00 Structure Description: 0 Single-Family D 2nd Dwel6ng Unit 0 Mobile Home (new spaces added) 0 Single-Family+ 2DU 0 Two-Four Unit 0 5 + Unit Structure l!!I Remodel/Reconstruction (new dwelling units added) 0 Commel"ciallResidential (miXed-use) Project's planned initial occupancy is for: II Rental occupant D 0wner occupant Do you intend to use this propel1y as your personal residence? 0 Yes Ill No If yes, please provide the estimated market value: $800,000 (Entire house) Will an affordable housing deed restriction be recoroed on the property? □Yes ■No Which units in the project will be deed restricled? _________________ _ Pleae indicate the number of units for each bedroom type that wlD be pn,vided and a price range. Individual responses wiU not be shared with oulslde parties. Number of units for sale Bedrooms per unit Price range (low and high) Studios $ 1 bd $ 2bd $ 3bd $ 4+bd $ Number of units for rent Bedrooms per unit Rent range (low and high) 1 Studios $15Q0.2000 1 bd $ 2bd $ 3bd $ 4+bd $ OWNER(S): Geesey, David A DEVELOPER(S): (last Fust. -1,-or Film Name) (last Fils!,_,,_ or Film Name) ADDRESS: 1640 Sandalwood Lane ADDRESS: CrTY, STAlE, ZIP: Carlsbad, CA 92008 CllY, STAlE,ZIP: lELEPHONE: SIGNATURE: TELEPHONE: DAlE: 1/7./2a,z I P-20 Page 1 of1 RiNised 10/10 PROPERTY LINE - ------------------- 3.00' V) "" co c.,; ;s. ;,.." a ,-,,' co yi Rl 2 --------- N 50·05'2o"E 78.00' CONG. BLOCK WALL ~OD FENCE 1640 SANDALWOOD LANE LOT 9 MAP 5757 APN 205-130-59-00 R = 373. 00' A = 46. 38' ~-X PROPERTY LINE 1----PROPERTY LINE V) "" co c.,; ;s. .i:,: a ,-,,' ~ '-J 0, Ct> !)J '-J Co ~ SANDALWOOD LANE 20 10 0 20 SCALE: 1" = 20' LEGEND e INDICATES FOUND 3/4" IRON PIPE W/DISC STAMPED "LS 2940" PER MAP 5757. \ INDICATES LINE STAKE. ( ) INDICATES RECORD DATA PER MAP 5757. SURVEYOR'S STATEMENT THIS MAP CORRECTLY REPRESENTS A SURVEY MADE BY ME IN CONFORMANCE WITH THE REQUIREMENTS OF THE PROFESS/ONA LAND SURVEYOR'S ACT AT THE REQUEST OF LAWRENCE AND DAVID GEESEY, ON FEBRUARY 02, 2021. ~~§ A:4NDA.MAR0:~ 5941 -z./qnpz, DAIE • ARMAND A. MAROIS PLS 5941 bliA,lnc. land planning, civil engineering, survayin 5115 Avenlda Encinas Suite L Carlsbad, California 92008-4387 (760) 931-8700 ,,(: Vi, 3:; :;~99 S,.J:\,:;,J;___f/CCC __,J:\;£ 5_,,r,-:JC":;e-scrc::::,wcc.-; :;;yq :,. QJ "' QJ QJ Cl lC) Cl Cl I 0, 0, 0, Cl I 0, 0, ·2') :::c ,::